Elevators typically include three separate braking systems: one for operational braking to hold an elevator car at respective landings, one for emergency braking for slowing the car if upward or downward speed of the car is too great, and one for safety braking to stop the car if a free-fall would otherwise occur. While some prior art systems combine two or more of these braking systems together into a single brake, such brakes have failed to correctly apply braking forces for each task. So, for example, a brake may provide both operational braking and emergency braking, but that brake may not be able to consistently apply correct braking forces and also consistently apply correct emergency braking forces.
The present disclosure relates generally to elevator braking systems using hydraulic pressure and spring forces to accomplish at least two of: (a) operational braking; (b) emergency braking; and (c) safety braking.
The following presents a simplified summary in order to provide a basic understanding of some aspects of the invention. This summary is not an extensive overview of the invention. It is not intended to identify critical elements of the invention or to delineate the scope of the invention. Its sole purpose is to present some concepts of the invention in a simplified form as a prelude to the more detailed description that is presented elsewhere.
In one embodiment, a hydraulic-boosted rail brake for use with an elevator having a guide rail includes a braking plate, a spring package, a hydraulic cylinder, a piston, and a brake controller. The braking plate has friction material and is selectively movable relative to the guide rail. The spring package is in communication with the braking plate and biases the friction material to interact with the guide rail, thereby causing braking. The piston is housed at least partially inside the hydraulic cylinder, is in communication with the braking plate, and is selectively: (a) movable in a release direction to weaken or overcome force from the spring package, and (b) movable in an engage direction to supplement the force from the spring package. The brake controller selectively causes the piston to move in the release direction and in the engage direction.
In another embodiment, a hydraulic-boosted rail brake for use with an elevator having a guide rail includes a braking plate, a spring package, a first hydraulic cylinder, a first piston, a second hydraulic cylinder, a second piston, and a brake controller. The braking plate has friction material and is selectively movable relative to the guide rail. The spring package is in communication with the braking plate and biases the friction material to interact with the guide rail, whereby causing braking. The first piston is housed at least partially inside the first hydraulic cylinder, is in communication with the braking plate, and is selectively movable in a release direction to overcome force from the spring package. The second piston is housed at least partially inside the second hydraulic cylinder, is in communication with the braking plate, and is selectively movable in an engage direction to supplement the force from the spring package. The brake controller selectively actuates the first piston and the second piston.
In still another embodiment, an elevator system includes an elevator car, a guide rail, structure for selectively moving the elevator car in opposed directions, and a hydraulic-boosted rail brake. The rail brake includes a braking plate, a spring package, and at least one hydraulically operated piston. The braking plate has friction material and is selectively movable relative to the guide rail. The spring package is in communication with the braking plate and biases the friction material to interact with the guide rail, thereby causing braking. The at least one hydraulically operated piston is in communication with the braking plate and is selectively: (a) movable in a release direction to weaken or overcome force from the spring package, and (b) movable in an engage direction to supplement force from the spring package.
A spring package 120 is in communication with the braking plate 110 and biases the friction material 112 to interact with the guide rail 15, causing braking. The spring package 120 may include one or more spring. In some embodiments, at least one helical spring may be used in the spring package 120. In alternate embodiments, magnetic springs or other types of springs or biasing mechanisms may be incorporated, whether now know or later developed. Regardless of the specific composition of the spring package 120, the spring package 120 is preferably fixed relative to the elevator car, and one part of the spring package 120 is operatively coupled to the braking plate 110. In some embodiments, spring package 120 outputs a sufficiently large compression force to catch a car during a safety braking operation or an emergency braking operation. In alternate embodiments, it may be permissible to use a spring package 120 that outputs less force upon the braking plate 110 than is common in the art such that the spring package 120 and a hydraulically operated piston 130 cooperate to output a sufficiently large compression force required to catch a car during safety braking operation or emergency braking operation. This may in turn reduce the weight of the rail brake 100 compared to prior art devices, resulting in less energy being required to operate the elevator.
Hydraulically operated piston 130 is also fixed relative to the elevator car, and includes a hydraulic cylinder 132 and a piston 133 housed at least partially inside the cylinder 132. The piston 133 is operatively coupled to the braking plate 110 and is a “double-acting” piston, selectively movable in opposite directions—a release direction 133a to diminish or overcome a force from the spring package 120, and an engage direction 133b to supplement the force from the spring package 120. A brake controller 140 selectively causes the piston 133 to move in the release direction 133a and in the engage direction 133b, as described further below.
Hydraulic fluid for the hydraulically operated piston 130 is housed in a pressurized tank 134, and a pump 135 maintains the pressure in the tank 134 using fluid from reservoir 136. The pump 135 may be in data communication with the controller 140 (e.g. through wired or wireless methods). A pressure sensor monitoring the fluid in the tank 134 may provide pressure data to the controller 140; that data may in turn be used to determine whether the pump 135 should be activated or deactivated to maintain a desired pressure. In an alternate embodiment (and especially if the desired pressure in the tank 134 is intended to be rarely changed), a mechanical pressure regulator in fluid communication with the tank 134 and the pump 135 may be used and data communication between the controller 140 and the pump 135 may be unnecessary. The mechanical pressure regulator may nevertheless be considered part of the brake controller 140 even if separate from other portions of the brake controller 140, however, as there is no requirement that the brake controller 140 consist of a unitary device or be contained in a single housing.
Continuing, a valve unit 150 is in data communication with the brake controller 140 and in fluid communication with the pressurized tank 134 as shown in
Sensors 160 may be in data communication with the brake controller 140 to provide various input useful in the operation and monitoring of the rail brake 100. The sensors 160 may include, for example, a position sensor associated with the piston 133 to provide positional data for the piston 133, the pressure sensor associated with the pressurized tank 134 previously discussed, a pressure sensor associated with each side of the piston 133 to provide pressure data for the hydraulic piston 130, and a sensor for determining velocity and acceleration of the elevator car.
To overcome or decrease a force from the spring package 120 on rail 15, the controller 140 may actuate the valve unit 150 to move the piston 133 in the release direction 133a.
So with the adjustments provided by the spring package 120 and the hydraulically operated piston 130, the rail brake 100 can function as an operational brake, as an emergency brake, and as a safety brake. For operational braking, the spring package 120 (either alone or with supplementation from the hydraulically operated piston 130) holds the car at respective landings. For emergency braking, the spring package 120, with selective cooperation from the hydraulically operated piston 130, applies appropriate forces to slow the car if upward or downward speed of the car is too great. And for safety braking, the spring package 120, with selective cooperation from the hydraulically operated piston 130, applies appropriate forces to stop the car if a free-fall would otherwise occur.
The extensive adjustments available through the spring package 120 and the piston 130 allow the controller 140 to precisely control the air gap between friction material 112 and rail 15. In some embodiments, the hydraulically operated piston 130 is manipulated to dampen the initial force applied by friction material 112 to the rail 156 from spring package 120, reducing the noise level and jerk associated with initial brake application. In other embodiments, the air gap may be minimized at low car speeds and maximized during high car speeds by varying the position of the piston 133 within the hydraulic cylinder 132. In yet other embodiments, the air gap may be dynamically reduced as a car decelerates.
Moreover, because the rail brake 100 includes both the spring package 120 and the hydraulically operated piston 130, the rail brake 100 has built-in redundancies important for safe operation. And in practice, it may be desirable to use multiple rail brakes 100 with a single elevator car to increase redundancies for safety and distribute braking forces being applied to the guide rail 15. When multiple rail bakes 100 are used, various parts (e.g., the pressurized tank 134, the pump 135, and the brake controller 140) may be shared across the rail brakes 100. In other embodiments, alternative brake units are used in the same elevator system as at least one rail brake 100. The hydraulically operated piston 130 of rail brake 100 can be used to compensate for failures and performance variations in the alternative brake units.
If the controller 140 determines that there is a leak or pressure failure (e.g., using data from the pressure sensor 160 associated with the pressurized tank 134, or using data from the sensors 160 associated with each side of the piston 133), the controller 140 may allow the friction material 112 to abut the guide rail 15 as shown in
For further illustration, the following Table 1 shows example variations of braking forces that may be achieved using one embodiment of the rail brake 100, assuming a braking retardation of 0.6 g.
Embodiment 500 replaces the double-acting piston 130 with two single-acting pistons 530a, 530b, and replaces the valve unit 150 with a valve unit 550 appropriate for actuating the piston 530a in the release direction 133a and actuating the piston 530b in the engage direction 133b. In use, as will be appreciated by those skilled in the art, the pistons 530a, 530b (operated by the valve unit 550) collectively provide the function of the piston 130.
Many different arrangements of the various components depicted, as well as components not shown, are possible without departing from the spirit and scope of the present invention. Embodiments of the present invention have been described with the intent to be illustrative rather than restrictive. Alternative embodiments will become apparent to those skilled in the art that do not depart from its scope. A skilled artisan may develop alternative means of implementing the aforementioned improvements without departing from the scope of the present invention. It will be understood that certain features and subcombinations are of utility and may be employed without reference to other features and subcombinations and are contemplated within the scope of the claims. The specific configurations and contours set forth in the accompanying drawings are illustrative and not limiting. All steps need not be performed in the order shown or described.