1. Field of the Invention
Aspects of the present disclosure may relate to door closers for automatic closing of doors, and in particular may relate to door closers with a latch boost feature and that may be regenerative.
2. Description of Related Art
Door closers are used to automatically close doors, hold doors open for short intervals, and control opening/closing speeds in order to facilitate passage through a doorway and to help ensure that doors are not inadvertently left open. A door closer is often attached to the top or bottom of a door, and when the door is opened and released, the door closer generates a mechanical force that causes the door to automatically close without any user input. Thus, a user may open a door and pass through its doorway without manually closing the door.
Many conventional door closers are designed such that when opened a spring is compressed and energy is stored in the spring. When the door is allowed to close the energy stored in the spring is used to return the door to the closed position. Many different arm configurations exist for creating a desired force curve in the opened and closed direction. However all configurations have less force available in the closing direction than was required to open the door due to mechanical losses of the system. Additionally most configurations have the same shape curve in the opening and closing direction. Because, more force is desired in the latch region during close to overcome the latching hardware, most configurations require significant force to begin opening the door. Additionally the force must be set high enough to close the door under adverse conditions, such as stack pressure, leading to even higher forces required to open the door at times when the adverse conditions are not present.
Many conventional door closers are mechanically actuated and have a plurality of valves and springs for controlling the varying amounts of force applied to the door as a function of door angle and/or speed, as described above. A typical door closer may also have function of door angle and/or speed, as described above. A typical door closer may also have a piston that moves through a reservoir filled with a hydraulic fluid, such as oil. Adjusting the valve settings in such a conventional door closer can be difficult and problematic since closing times can vary because of the systems dependency on temperature, pressure, wear, and installation configuration. Moreover, adjusting the valve settings in order to achieve a desired closing profile for a door can be burdensome for at least some users. Many door closers exhibit much less than ideal closing characteristics because users are either unwilling or unable to adjust and re-adjust the valve settings in a desired manner or are unaware that the settings can and may need to be changed in order to effectuate a desired closing profile in the face of temperature changes, wear over time, and/or modifications to the physical installation.
Bearing in mind the problems and deficiencies of the prior art, it is therefore an object of the present invention to provide an apparatus and method for determining angle of door opening and applying force to resist and slow the door as it approaches and/or passes a predetermined angle of opening.
It is another object of the present invention to provide an apparatus and method for determining when an assist is needed to complete closing of the door, and thereafter applying force to assist the door in closing to the closed position.
A further object of the invention is to provide an apparatus and method for determining when an assist is needed to complete closing of the door by door position, speed and/or time of closing.
It is yet another object of the present invention to provide an apparatus and method for applying force to assist the door in closing to the closed position from energy generated and stored exclusively by the motion of the door, without the use of any external power source.
It is a further object of the present invention to provide an apparatus and method for applying more force to the door to assist in closing than was generated by opening the door.
Still other objects and advantages of the invention will in part be obvious and will in part be apparent from the specification.
Embodiments of a door closer disclosed herein may be realized by a motorized door closer that may electrically create a “latch boost” for causing a door to latch. The latch boost in such embodiments may be created by electrical control of the motor. The door closer in some embodiments may be self-powered by causing the motor to act as a generator to charge a battery or capacitor, and self-adjusting through control of the motor with known motor control means.
The above and other objects, which will be apparent to those skilled in the art, are achieved in the present invention which is directed to a door closer comprising an electric motor configured to be operatively connected to a door, wherein the drive shaft of the electric motor rotates when the door moves in the direction of closing, and the door moves in the direction of closing in response to the rotation of the drive shaft of the electric motor. The door closer includes a position sensor for determining the position of the door and a controller to control the electric motor including a processor configured to receive input from the position sensor. When the position sensor indicates that the door is in a latch boost region or the controller otherwise determines that a motor assist is needed, the controller causes the electric motor to be powered to apply force to assist the door in closing.
The door closer may include a spring adapted to bias the door toward the closed position. When the door moves in the direction of closing and the electric motor is not powered, the electric motor acts as a generator and generated power is stored in an energy storage element. When the door moves in the direction of opening, the electric motor is not powered, and the electric motor acts as a generator and generated power is stored in the energy storage element.
The door position sensor may be a potentiometer or rotary encoder, and the processor may receive input from the potentiometer or rotary encoder for determining the door position and the closing speed of the door. The position sensor may operate by sensing proximity of a magnet or may comprise a Hall effect device.
The door closer may include a potentiometer that controls electrical resistance across the motor/generator or other means for varying input and/or output power to/from the motor/generator to control the rotation of the electric motor and slow/quicken the closing speed of the door. The processor may be programmed to control the potentiometer or other means of control to automatically adjust the closing speed of the door.
The door closer may include a memory, wherein the processor is operatively connected to the electric motor, the position sensor, and the memory, wherein the processor determines that the door is within the latch boost region or otherwise detects that a motor assist is needed and control the electric motor to exert a closing force on the door. The control of the electric motor to exert a closing force on the door may be accomplished by injecting or applying a voltage into the motor, or using other motor control methods.
In another aspect the present invention is directed to a method of operating a door closer using a controller and an electric motor. The method comprises determining that a door to which the door closer is attached is attempting to close through a latch boost region or that the door to which the door closer is attached is attempting to close is encountering conditions appropriate for motor assistance; and using the controller to cause the door closer, through electronic control of the electric motor, to exert a force to assist the closing of the door until the door closes.
The electronic control of the electric motor may comprise injecting or applying a voltage into the electric motor. The determining that the door is attempting to close through the latch boost region or that the door to which the door closer is attached is encountering conditions appropriate for motor assistance may comprise the controller receiving a position signal. The position signal can originate from a position sensor that may sense proximity indicating the door is in the latch boost region such as with a magnet and/or Hall effect sensor, or may sense angular position of the door as in a potentiometer and determine if conditions are appropriate for motor assistance. The controller may adjust the current through the motor/generator by controlling the resistance across the motor/generator or by controlling the current output of the motor/generator to vary the closing speed of the door based on input from the position sensor. The method may further comprise storing the generated power in an energy storage element.
In a further aspect the present invention provides a door closer comprising an electric motor/generator configured to be operatively connected to a door movable between a closed position and an open position. The electric motor/generator has a drive shaft which rotates when the door moves in the direction of opening and in the direction of closing. The motor/generator is configured to apply force to move the door in the direction of closing in response to the rotation of the drive shaft of the electric motor/generator. The door closer also includes a position sensor for determining the position of the door, including door position in the vicinity of the closed position, an electrical energy storage element connected to the motor/generator and configured to store electrical energy generated by the electric motor/generator as the door moves in the direction of opening or closing, and a motor/generator controller connected to the position sensor and motor/generator. The controller receives input from the position sensor and controlling operation of the electric motor/generator. The controller determines when a motor assist is needed to complete closing of the door, and thereafter causes the electric motor/generator to be powered by electrical energy generated by the electric motor/generator and stored in the electrical energy storage element to apply force to assist the door in closing to the closed position.
The position sensor may determine the position of the door at any position between the closed and open positions, or only in the vicinity of the closed position. The controller causes the electric motor/generator to apply force to assist the door in closing to the closed position based on the position sensor indicating that the door is in the vicinity of the closed position. The door closer may have a spring adapted to bias the door toward the closed position.
When the door moves in the direction of closing and the electric motor/generator is not powered, the electric motor/generator acts as a generator and generated power is stored in an energy storage element. When the door moves in the direction of opening, the electric motor/generator is not powered, and the electric motor/generator acts as a generator and generated power is stored in the energy storage element.
The door position sensor may be a potentiometer or a proximity switch. The proximity switch may indicate if the door is in the closed position. The position sensor may operate by sensing proximity of a magnet, or the position sensor may comprise a Hall effect device.
The door closer may include a potentiometer that controls electrical resistance to control the rotation of the electric motor/generator and slow the closing speed of the door. The motor/generator controller may include a processor programmed to control the potentiometer or other means for varying load on the motor/generator to automatically adjust the closing speed of the door. The door closer may include one or more motor control circuits operatively connected to the controller to permit the controller to control current in the motor/generator. The motor control circuits may include high and low gates in a half H-bridge configuration, or in a full H-bridge configuration.
The door closer may further including a memory operatively connected to the controller. The controller receives data from the memory to determine that a motor assist is needed and control the electric motor/generator to exert a closing force on the door.
The electric motor/generator may be powered exclusively by electrical energy generated by the electric motor/generator and stored in the electrical energy storage element. When the door moves in the direction of closing, the electric motor/generator may act as a brake on the rate of closing of the door. The control of the motor/generator to exert a closing force on the door may be accomplished by applying a voltage to the motor.
When a predetermined angle of door opening is reached, load on the motor/generator may be increased to resist opening further. The load on the motor/generator may be varied to resist the opening of the door to prevent the door from opening at an excessive rate. The door excessive rate may be defined as moving above a predetermined speed. The door closer may include a spring adapted to bias the door toward the closed position. The door excessive rate may consist of the door moving at a rate such that the kinetic energy of the door is greater than the energy that will be absorbed by the spring and losses as the door travels to a predetermined point.
In another aspect, the present invention provides a door closer comprising an electric motor/generator configured to be operatively connected to a door movable between a closed position and an open position. The electric motor/generator has a drive shaft that rotates when the door moves in the direction of opening and in the direction of closing. The motor/generator is configured to apply force to resist movement of the door in the opening and closing position. The door closer further includes a position sensor for determining the position of the door, an electrical energy storage element connected to the motor/generator and configured to store electrical energy generated by the electric motor/generator as the door moves in the direction of opening or closing, and a motor/generator controller connected to the position sensor and motor/generator. The controller receives input from the position sensor and controls operation of the electric motor/generator. The controller determines the load to apply to the motor/generator to control the speed of the door. The door closer is powered exclusively by electrical energy generated by the electric motor/generator and stored in the electrical energy storage element.
In a related aspect the invention is directed to a method of operating a door closer using an electric motor/generator operatively connected to a door movable between a closed position and an open position. The method comprises storing electrical energy generated by the electric motor/generator as the door moves in the direction of opening or closing, determining that a motor assist is needed to complete closing of the door, and causing the electric motor/generator to be powered by the stored electrical energy generated by the electric motor/generator to apply force to assist the door in closing to the closed position.
The method may further include determining the position of the door between the closed and open positions, and using the determined door position to determine that a motor assist is needed to complete closing of the door. The method may include determining the position of the door in the vicinity of the closed position, and using the determined door position to determine that a motor assist is needed to complete closing of the door. The method may include determining whether the door has not closed within a predetermined acceptable closing time, and using the determined door closing time to determine that a motor assist is needed to complete closing of the door. The method may include determining that the door is not closing with a predetermined acceptable closing speed, and using the determined door closing speed to determine that a motor assist is needed to complete closing of the door.
When the door moves in the direction of closing and the electric motor/generator is not powered, the electric motor/generator may act as a generator and generated power is stored. When the door moves in the direction of opening, the electric motor/generator is not powered, and the electric motor/generator may act as a generator and generated power is stored.
The method may comprise causing the electric motor/generator to be powered by the stored electrical energy generated by the electric motor/generator to vary the closing speed of the door.
The method may include storing energy in a spring as the door moves in the direction of opening and using the stored spring energy to move the door in the direction of closing. The electric motor/generator may be powered exclusively by stored electrical energy generated by the electric motor/generator. The electric motor/generator may be caused to be powered by the stored electrical energy generated by the electric motor/generator by applying a voltage to the motor.
The features of the invention believed to be novel and the elements characteristic of the invention are set forth with particularity in the appended claims. The figures are for illustration purposes only and are not drawn to scale. The invention itself, however, both as to organization and method of operation, may best be understood by reference to the detailed description which follows taken in conjunction with the accompanying drawings in which:
In describing the preferred embodiment of the present invention, reference will be made herein to
Certain terminology is used herein for convenience only and is not to be taken as a limitation on the embodiments described. For example, words such as “top”, “bottom”, “upper,” “lower,” “left,” “right,” “horizontal,” “vertical,” “upward,” and “downward” merely describe the configuration shown in the figures. Indeed, the referenced components may be oriented in any direction and the terminology, therefore, should be understood as encompassing such variations unless specified otherwise.
As used herein, the term “open position” for a door means a door position other than a closed position, including any position between the closed position and a fully open position as limited only by structure around the door frame, which can be up to 180° from the closed position.
The present invention is directed to a door closer with an electric motor-assisted closing feature, provided by a motor/generator. Embodiments disclosed herein provide a regenerative oilless door closer with the latch boost closing feature. The door closer may have a spring that provides almost all of the closing force. The embodiment described does not include a cylinder with hydraulic fluid, however, one could be provided. A motor may provide additional force to assist the door in latching to overcome external forces. When the door is closing as the result of the force of the spring, the motor may be backdriven. The backdriving of the motor makes the motor into a generator, and the inefficiencies of the motor as well as electrical energy conversion may slow the closing speed of the door. The motion of the opening of the door may also drive the motor and cause the motor to generate power. Generated power may be stored in an energy storage element, such as a battery or capacitor.
As the door moves to close by the force of the spring, the motor may be driven to collect power, and a capacitor or battery may be charged, making the door closer regenerative. Metering of power generation may be performed with a varied resistance or through a regenerative braking circuit/algorithm. The varied generated current can be used to increase or decrease the energy converted to electricity, and accordingly controls the motor speed when the motor is acting as a generator, which controls the closing speed of the door in opposition to the spring. Inefficiencies of the motor also contribute to slowing door closing speed. Power that is left over or unused during the closing of the door may be captured and stored or converted to heat. When the latch boost is needed, voltage is injected or applied to the motor to drive the motor and cause the door to latch. In one embodiment, a position sensor such as a potentiometer or proximity switch determines the door position. A speed sensor such as a rotary encoder may also be used to determine the door position and closing speed. The sensor communicates with a control unit, which includes a processor and engages the motor when the latch boost force is needed.
Referring now to the drawings, an embodiment of a door closer is shown in
Continuing with
Still referring to
Referring now to
The control unit 44 (
The control unit 44 is part of an overall control system which may include a door position sensor, such as a potentiometer or proximity sensor, optionally a speed and position sensor, such as a rotary encoder, and a potentiometer in electrical communication with the control unit 44 for allowing a user to selectively control the delivery of electrical energy to the motor and to control the closing speed of the door 32 by varying the resistance provided by the motor 42.
The operator arm assembly 46 includes a linkage arm 60 that is mounted on and rotated by vertical shaft 51 on which the pinion 50 is mounted. The pinion 50 engages the rack 52. The rack 52 is urged to move by force of a spring 66 against the mounting for shaft 51 and pinion 50. When the door 34 is open, the rack 52 may be at one end of its range of motion, and when the door 32 is closed, the rack 52 may be at the other end of its range of motion. When the rack 52 moves as a result of force from the spring 66, the pinion 50 and shaft 51 rotate, driving the linkage arm 60 to close the door. There is a sprocket 70 mounted to the side of the pinion 62 opposite the linkage arm 60, and the sprocket 70 engages a chain 72. When the rack moves as the result of force from the spring 66, the sprocket 70 drives the chain 72. At the other end of the chain 72 is another sprocket 74. This sprocket 74 is caused to turn by the chain 72, and turns an axle 75 that has another sprocket 76 (
In the embodiment shown, the pinion 62, in addition to engaging the rack 64 may optionally be utilized by an optical, magnetic, or mechanical rotary encoder (not shown in
In use, upon the initial movement of the door 32 being opened, the rotary encoder (if used) is activated. The encoder signals the control unit 44, which converts the input to functions of door position and speed of displacement. A potentiometer may be used to control the resistance of the motor 42, which in turn may be used to slow the door closing speed, although other features are also available to control closing speed. The potentiometer and microprocessor may regulate the speed of closing by setting the potentiometer and the microprocessor trying to keep that speed. Regenerative braking by using the motor in the generator mode may be employed. Desired closing speed may be programmed into the control unit 44, and the closer 30 may be self-adjusting by the control unit 44 controlling the resistance through the potentiometer with the input of position and speed from the encoder. The position sensor may be used to monitor the position of the door throughout parts or all of the full sweep from closed to open, and back to closed, but it is important that the position sensor be able to determine when additional closing force is needed, such as when the door reaches the latch range (32b in
The determination of whether the door will need assistance to latch may also be done by timing the operation and determining when the door has not closed within a predetermined acceptable closing time. The self-adjusting capability of the closer 30 activates by the controller if there is additional resistance or time to closing, such as from a gust of wind. The additional closing time will be detected by a timer or other time monitoring device or sensor, communicated to the control unit 44, and additional voltage can be injected or applied to the motor 42 to cause the door 32 to close. For example, a time sensor or timer can be used to determine whether the door has closed within a predetermined acceptable closing time, for example about 2 to 10 seconds or more.
A door position sensor with or without an encoder may be used. The position sensor may be used to monitor the position of the door throughout parts or all of the full sweep from closed to open, and back to closed, but it is important that the position sensor be able to determine when additional closing force is needed, such as when the door reaches the latch range (32b in
In the example embodiments described herein, the control system includes components 680 to provide setup parameters to the controller. These components include potentiometers and dip switches. In one example, potentiometers are provided for closing force, obstruction sensitivity, motor delay, and the force by which the door is held closed against a doorframe. A dipswitch is provided to set the door closer for either left hand or right hand operation. Obstruction sensitivity determines how hard the door will push on an obstruction when opening before stopping. In some embodiments, these input components are monitored continuously to determine the operating parameters of the door closer. However, it is possible to design an embodiment where these settings are stored in a memory 654. In such an embodiment, the input components are read at start-up. It is also possible to design an embodiment where these parameters are put in the memory 654 through the programming interface 604 rather than input via connected components such as potentiometers or switches. The potentiometer for controlling resistance at the motor may be adjusted manually, may adapt automatically, or may be preset to control the door closing speed.
The power module 606 of
Controller 602 in this example embodiment includes a central processing unit (CPU) 652 and memory 654. Many different types of processing devices could be used to implement an embodiment of the present disclosure, including a processor, digital signal processor, or so-called, “embedded controller.” Any of these devices could include memory along with a processing core such as a CPU, or could use external memory or a combination of internal and external memory. In the illustrated embodiment the memory stores firmware or computer program code for executing a process or method on the CPU or other processor to carry out an embodiment of the present disclosure. Such firmware or computer program code can be loaded into the control unit from an external computer system via programming interface 604. The process or method of an embodiment of the present disclosure could also be carried out by logic circuitry, a custom semiconductor device, or a combination of such a device or circuitry with firmware or software. As previously mentioned, in some embodiments the memory could also be used to store operating parameters.
An embodiment of an electric door closer may take the form of an entirely hardware embodiment, or an embodiment that uses software (including firmware, resident software, micro-code, etc.). Furthermore, an embodiment may take the form of a computer program product on a tangible computer-usable storage medium having computer-usable program code embodied in the medium. A memory device or memory portion of a processor as shown in
Another embodiment of the door closer of the present invention is shown in
In the embodiment of
As shown in
The voltage injection or application to the motor during the assist phase in the embodiment disclosed is accomplished by applying a continuous DC voltage to the motor from a battery or capacitor. The voltage level may be fixed relative to the position of the door; however, the voltage may be varied or changed depending on the exact position of the door with use of the aforediscussed position or speed sensors and appropriate programming of the controller. A pulsed voltage may also be applied to the motor to create the assist force, such as during latch boost.
The present invention may also be used to apply force from the motor/generator to resist the door opening beyond a predetermined angle of opening called the back check region 101 shown in
A method of practicing the assistance boost aspect of the invention is shown in process 900 of the flowchart of
The present invention therefore achieves one or more of the objects described above. The door closer is able to determine angle of door opening and apply force from a motor/generator to resist the door opening beyond a predetermined angle of opening. The door closer is able to determine when a motor assist is needed to complete closing of the door, and thereafter apply force to assist the door in closing to the closed position. The assistance determination is able to be made by door position, speed or time of closing. The electric motor/generator that provides the force assistance is powered by electrical energy generated exclusively by the electric motor/generator and stored in the electrical energy storage element. The door closer is able to provide more force upon closing during the latch boost or other assistance phases than just the spring from potential energy by using the generated power during the opening and/or closing cycle. The door closer is able to store electrical energy in the electrical energy storage element over multiple door opening and closing cycles, so that the energy used by the assist may be more than that stored during the same opening/closing cycle.
The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the present disclosure. As used herein, the singular forms “a”, “an” and “the” are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will be further understood that the terms “comprises” and/or “comprising,” when used in this specification, specify the presence of stated features, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, steps, operations, elements, components, and/or groups thereof. Additionally, comparative, quantitative terms such as “less” or “greater” are intended to encompass the concept of equality, thus, “less” can mean not only “less” in the strictest mathematical sense, but also, “less than or equal to.”
Although specific embodiments have been illustrated and described herein, those of ordinary skill in the art appreciate that any arrangement which are calculated to achieve the same purpose may be substituted for the specific embodiments shown and that the present disclosure has other applications in other environments. This application is intended to cover any adaptations or variations of the present disclosure. The following claims are in no way intended to limit the scope of the present disclosure to the specific embodiments described herein.
Filing Document | Filing Date | Country | Kind |
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PCT/US2014/028190 | 3/14/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2014/152907 | 9/25/2014 | WO | A |
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