This application relates to a hoist system and control of a hoist system.
The concepts described in this application relate to hoist systems. Hoist system are used by professionals in a variety of industries to lift and maneuver various loads, support work surfaces, support humans in varying work environments, etc. Control of hoist system, particularly when lifting or maneuvering large and/or heavy loads is usually done via one or more push button controllers which do not always allow precision control of the load being moved.
Zero-gravity hoist systems described herein include a chain fall, a motor coupled to the chain fall and configured to drive the chain fall in one or more directions, a power supply configured to provide power to the motor, and a controller having one or more electronic processors. The one or more electronic processors are configured to measure a first force of a load in response to receiving an input, store the measured first force in a memory of the controller, measure a second force of the load, determine a difference between the second measured force and the first measured force, and adjust a height of the load based on determining that the second force differs from the first force by a predetermined threshold.
In some aspects, the one or more electronic processors are further configured to lower the height of the load based on determining that the second force is greater than the first force by at least the predetermined threshold.
In some aspects, the one or more electronic processors are further configured to raise the height of the load based on determining that the second force is less than the first force by at least the predetermined threshold.
In some aspects, the motor is a brushless direct current motor.
In some aspects, the power supply is a lithium-based battery pack.
In some aspects, the lithium-based battery pack is a power tool battery pack.
In some aspects, the zero-gravity hoist system further includes a load sensing assembly configured to determine the force of the load attached to the chain fall. The load sensing assembly is positioned between the chain fall and a support or the load. The load sensing assembly includes a spring plate configured to deflect in a first direction when the force of the load increases, and a first sensor configured to apply a first electrical signal to a first conductive surface associated with the spring plate. The first sensor includes a first antenna configured to receive a signal from the first conductive surface, wherein the first electrical signal is dependent on a distance between the first antenna and the first conductive surface. The load sensing assembly also includes a sensor circuit configured to receive an input from the first antenna representative of the distance between the first antenna and the first conductive surface. The load sensing assembly is configured to transmit the determined force to the controller.
Hoist systems described herein include a battery pack powered hoist device and a load sensing assembly. The load sensing assembly is configured to determine a force of a load attached to the hoist device. The load sensing assembly is positioned between the hoist device and a support or a load. The load sensing assembly includes a spring plate configured to deflect in a first direction when the load increases, a first sensor, and a sensor circuit. The first sensor is configured to apply a first electrical signal to a first conductive surface associated with the spring plate. The first sensor includes a first antenna configured to receive a signal from the first conductive surface. The first electrical signal is dependent on a distance between the first antenna and the first conductive surface. The sensor circuit is configured to receive an input from the first antenna representative of the distance between the first antenna and the first conductive surface.
In some aspects, the sensor circuit includes a tank circuit configured to detect a change in inductance in the first electrical signal from the first sensor.
In some aspects, the change in inductance is proportional to the distance between the first antenna and the first conductive surface.
In some aspects, the load sensing assembly further includes a second sensor configured to apply a second electrical signal to second conductive surface associated with the spring plate. The second sensor includes a second antenna configured to receive a second signal from the second conductive surface. The second electrical signal is dependent on a second distance between the second antenna and the second conductive surface.
In some aspects, the first sensor and the second sensor are located mechanically opposite of each other.
In some aspects, the first electrical signal and the second signal are provided to the sensor circuit as differential output signals.
In some aspects, the hoist system also includes a chain fall, a motor coupled to the chain fall, and configured to drive the chain fall in one or more directions, and a controller in communication with the load sensing assembly and having one or more electronic processors. The one or more electronic processors are configured to receive an input from a user indicating that the load coupled to the chain fall is at a desired height, receive a first force of the load from the load sensing assembly in response to receiving the input, and store the measured force in a memory of the controller. The processors are also configured to receive a second force of the load from the load sensing assembly, determine a difference between the second measured force and the first measured force, and adjust the height of the load based on determining that the second force differs from the first force by a predetermined threshold.
Zero-gravity hoist systems described herein include a hoist and a motor coupled to the hoist configured to drive the hoist in one or more directions. The zero-gravity hoist system also includes a load sensing assembly configured to determine a force of a load attached to the hoist. The load sensing assembly is positioned between the hoist and a support or the load, the load sensing assembly includes a spring plate configured to deflect in a first direction when the load increases, and a first sensor configured to apply a first electrical signal to a first conductive surface associated with the spring plate. The first sensor includes a first antenna configured to receive a signal from the first conductive surface. The first electrical signal is dependent on a distance between the first antenna and the first conductive surface. The load sensing assembly also includes a sensor circuit configured to receive an input from the first antenna representative of the distance between the first antenna and the first conductive surface. The zero-gravity hoist system also includes a power supply configured to provide power to the motor, and a controller having one or more electronic processors. The one or more electronic processors are configured to receive a first force of the load from the load sensing assembly in response to receiving an input, store the received first force in a memory of the controller, receive a second force of the load from the load sensing assembly, determine a difference between the second measured force and the first measured force, and adjust a height of the load based on determining that the second force differs from the first force by a predetermined threshold.
In some aspects, the one or more electronic processors are further configured to lower the height of the load based on determining that the second force is greater than the first force by at least the predetermined threshold.
In some aspects, the one or more electronic processors are further configured to raise the height of the load based on determining that the second force is less than the first force by at least the predetermined threshold.
In some aspects, the sensor circuit includes a tank circuit configured to detect a change in inductance in the first electrical signal from the first sensor.
In some aspects, the change in inductance is proportional to the distance between the first antenna and the first conductive surface.
In some aspects, the load sensing assembly further includes a second sensor configured to apply a second electrical signal to a second conductive surface associated with the spring plate. The second sensor includes a second antenna configured to receive a second signal from the second conductive surface, wherein the second electrical signal is dependent on a second distance between the second antenna and the second conductive surface.
Before any embodiments are explained in detail, it is to be understood that the embodiments are not limited in its application to the details of the configuration and arrangement of components set forth in the following description or illustrated in the accompanying drawings. The embodiments are capable of being practiced or of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein are for the purpose of description and should not be regarded as limiting. The use of “including,” “comprising,” or “having” and variations thereof are meant to encompass the items listed thereafter and equivalents thereof as well as additional items. Unless specified or limited otherwise, the terms “mounted,” “connected,” “supported,” and “coupled” and variations thereof are used broadly and encompass both direct and indirect mountings, connections, supports, and couplings.
In addition, it should be understood that embodiments may include hardware, software, and electronic components or modules that, for purposes of discussion, may be illustrated and described as if the majority of the components were implemented solely in hardware. However, one of ordinary skill in the art, and based on a reading of this detailed description, would recognize that, in at least one embodiment, the electronic-based aspects may be implemented in software (e.g., stored on non-transitory computer-readable medium) executable by one or more processing units, such as a microprocessor and/or application specific integrated circuits (“ASICs”). As such, it should be noted that a plurality of hardware and software based devices, as well as a plurality of different structural components, may be utilized to implement the embodiments. For example, “servers,” “computing devices,” “controllers,” “processors,” etc., described in the specification can include one or more processing units, one or more computer-readable medium modules, one or more input/output interfaces, and various connections (e.g., a system bus) connecting the components.
Relative terminology, such as, for example, “about,” “approximately,” “substantially,” etc., used in connection with a quantity or condition would be understood by those of ordinary skill to be inclusive of the stated value and has the meaning dictated by the context (e.g., the term includes at least the degree of error associated with the measurement accuracy, tolerances [e.g., manufacturing, assembly, use, etc.] associated with the particular value, etc.). Such terminology should also be considered as disclosing the range defined by the absolute values of the two endpoints. For example, the expression “from about 2 to about 4” also discloses the range “from 2 to 4”. The relative terminology may refer to plus or minus a percentage (e.g., 1%, 5%, 10%, or more) of an indicated value.
It should be understood that although certain drawings illustrate hardware and software located within particular devices, these depictions are for illustrative purposes only. Functionality described herein as being performed by one component may be performed by multiple components in a distributed manner. Likewise, functionality performed by multiple components may be consolidated and performed by a single component. In some embodiments, the illustrated components may be combined or divided into separate software, firmware and/or hardware. For example, instead of being located within and performed by a single electronic processor, logic and processing may be distributed among multiple electronic processors. Regardless of how they are combined or divided, hardware and software components may be located on the same computing device or may be distributed among different computing devices connected by one or more networks or other suitable communication links. Similarly, a component described as performing particular functionality may also perform additional functionality not described herein. For example, a device or structure that is “configured” in a certain way is configured in at least that way but may also be configured in ways that are not explicitly listed.
Other aspects of the embodiments will become apparent by consideration of the detailed description and accompanying drawings.
Embodiments described herein relate to various systems for controlling a hoist or lifting system to, among other things, achieve fine movements of a suspended load with minimal force by a user. The following examples of hoist control systems are not exhaustive, and alternative or modified methods and configurations are also contemplated.
The hoist 104 is further coupled to a load cable 108, which couples the hoist to a load 110. Similar to the cable 102, the load cable 108 may be a wire cable, a rope, a chain, a hybrid, and the like. The hoist 104 is configured to extend or retract the load cable 108 in order to move the load in a longitudinal direction (e.g. up or down). In some embodiments, the hoist 104 includes an electric motor to extend or retract the load cable 108. However, in other examples, mechanical winches or other mechanisms may be used. The hoist 104 may be controlled via a wired or wireless remote-control system operable by a user to control the operation of the hoist 104.
Turning now to
In one embodiment the remotes may include one or more accelerometers configured to translate a movement of the remotes 204 in free space by a user. The accelerometers may provide a signal indicative of a movement of the remotes 204 to the hoist controller 206, which then controls the hoist 104 to move load 202 in a manner that corresponds to the movement of the one or more remotes 204. For example, a user may hold a remote 204 in a horizontal orientation and move the remote 204 up or down along a longitudinal axis. The accelerometers determine the movement of the remote 204 and transmit a signal indicative of the determined movement to the hoist controller 206, which then moves the load 202, via the hoist 104, in a manner that corresponds to the movement of the remote 204. In some embodiments, the amount of movement, e.g. movement along the longitudinal axis, may also be detected by the accelerometers, and used to control a speed of movement of the hoist 104 via the host controller 206. In some examples, the accelerometers within the remotes 204 may be configured to determine an orientation of the remote 204 (e.g. horizontal, vertical). The accelerometers can then determine a longitudinal movement of the remotes and provide that information to the hoist controller regardless of the orientation of the remote 204 when being operated by a user.
Turning now to
The hoist controller 206 may then control the hoist based on the amount of force applied by the user to the load sensors 306, as well as the accelerometer data from the accelerometer 308. For example, if the user applies a downward pressure on the load 302, the hoist controller 206, based on data from the load sensors 306 and the accelerometer 308, controls the hoist to lower the load. In some examples, the speed at which the load 302 is moved is controlled based on the amount of pressure applied by the user and measured by the load sensors 306. This can allow a user to control the movement of the load by touch only and allow for the user to stop movement of the load 302 simply by ceasing to touch the load 302. As described above, the use of the hoist-controlling gloves 304 may be used to allow a user to perform fine adjustments to a suspended load, whereas gross movements may be controlled using a standard hoist controller.
Turning now to
As will described in more detail below, the load sensor 404 may be configured to set a baseline of the load 402 when the load 402 is in a desired position (e.g., when gross movements are no longer required). The load sensor 404 may then detect changes in the load 402 and provide a signal indicative of those changes to the load controller 206. The load controller 206 may then control the hoist 104 to raise or lower the load 402 based on the determined change at the load sensor 404.
For example, a user may apply an upward force to the load 402, and the load sensor 404 detects a corresponding reduction in the measured load over the established baseline loading. This reduction is then provided to the hoist controller 206, which then controls the hoist 104 to raise the load. Similarly, a user may provide a downward pressure on the load 402, and the load sensor 404 will then subsequently detect a corresponding increase in the measured load over the established baseline loading. This increase in load is then conveyed to the hoist controller 206, which then controls the hoist 104 to lower the load 402. Once the change in load is removed, the hoist controller 206 can stop the hoist 104 to prevent additional movements of the load 402. In some embodiments, a minimum load change is required by the hoist controller 206 to initiate a movement of the load 402, such as ±5 lbs. However, other minimum load changes of more than 5 lbs. or less than 5 lbs. are also contemplated. In other embodiments, the load controller 206 may base the minimum on a percentage of the measured load, such as 1%. Thus, if the load weighs 1000 lbs., a change of 10 lbs. or more will be required to initiate a movement by the hoist controller 206. However, percentage of more than 1% or less than 1% are also contemplated. This allows for the load controller 206 to dynamically adjust to the mass of the load 402.
The zero-gravity hoist control system 400 allows for oscillations within the operation of the hoist 104 to be reduced by requiring positive feedback from the user input. For example, the force applied by the user directly correlates to the desired movement of the load, thereby reducing constant adjustments by a user using a known remote-control device to perform the fine manipulations of the load 402. Additionally, by requiring a user to physically manipulate the load 402 (i.e. apply an upward or downward force to the suspended load), accidental inputs are avoided as there must be an affirmative application of force to the load 402.
Turning now to
In one embodiment, the power source 502 is a removable battery pack, such as a lithium ion battery pack configured for use with a power tool. For example, the power source 502 may be an 18 VDC Li-Ion battery pack. In other examples, the power source 502 is a dedicated battery and/or an AC line connection (e.g. 120 VAC, 240 VAC, etc.). The power source 502 provides power to the controller power supply 504, which is configured to convert the power source voltage level to a voltage usable by the controller (e.g. 12V, 5V, 3.3V, etc.).
The controller power supply 504 provides power to the controller 506. In one embodiment, the controller 506 is an Arduino Due. However, the controller 506 may be other controller types, such an application specific integrated circuit (ASIC), a field programmable grid array (FPGA), a programmable microprocessor, a group of processing components, or other suitable electronic processing components. The controller 506 may be coupled to or include control logic 518. For example, in some embodiments, the control logic 518 may be software stored on a memory of the controller 506 that is executed by a processor of the controller 506, and in some embodiments, the control logic 518 includes a separate circuit or controller coupled to the controller 506. The control logic 518 is configured to determine how the hoist motor 512 should be controlled based on inputs provided by the motor controller 510, the load sensor 508, and/or the remote control 516. For example, the control logic 518 may be configured to perform the zero-gravity function as used by the zero-gravity hoist control system 400 described above. The control logic 518 associated with the zero-gravity hoist control system 400 will be discussed in more detail below.
The load sensor 508 is configured to detect a load on the hoist 104 or as applied to a load cable, such as when the hoist is lifting a load. As shown in
In one embodiment, the load sensor 508 is coupled to the controller 506 via a wired connection. However, in other embodiments, the load sensor 508 may be connected to the controller 506 via a wireless connection, such as RF, Bluetooth, NFC, and the like. As will be described in more detail below, the load sensor 508 provides load data to the controller 506 which is then processed by the control logic 518 to ensure the proper control of the hoist motor 512.
The motor controller 510 is configured to control the hoist motor 512 based on a control signal provided by the controller 506. In some embodiments, the motor controller 510 is a dedicated motor controller for controlling a brushless DC motor. However, the motor controller 510 may be configured as other types of motor controllers depending on the hoist motor 512 type. The motor controller 510 may further include one or more sensor circuits 520. The sensor circuits 520 may be configured to receive sensor feedback data provided by the hoist motor 512. For example, where the hoist motor 512 is a brushless DC motor, the sensor circuits 520 are configured to receive Hall sensor data from the hoist motor. The Hall sensor data may be used by both the motor controller to control the operation of the hoist motor 512, as well as the controller 506 as feedback data relating to speed, position, etc. Other sensor data may include temperature data, motor speed data, etc.
The power conditioner 514 may be configured to provide conditioned power from the power source 502 to the remote control 516, and various components therein, such as the load sensor 508. In some embodiments, the power conditioner 514 is contained within the remote control 516. However, in other examples, the power conditioner 514 is separate from the remote control. Providing conditioned power to the remote control 516 can be used to reduce electrical noise in the remote-control circuit in order to improve operation. The remote control may be configured to allow a user to control specific functions of the hoist system 400. For example, the remote control 516 may have actuators or other inputs to perform various functions, such as UP, DOWN, or Emergency Stop (E-STOP). These controls may be used to perform gross movements of a hoist. The remote control may further include an actuator or other input to enact a “FLOAT” mode. The FLOAT mode may be used to enter a zero-gravity mode, as described above. For example, when the user actuates the FLOAT input, the controller 506 may determine a load on the hoist system, and, once the baseline load is established, allow the user to move the load up and down by applying a force to the load as described above. This control scheme is described in more detail below.
Turning now to
The output of the process block 602 is then summed with a measured load from the force sensor 608 at summing block 612 to generate a signal representative of a difference between the current load and the baseline load. The output of the summing block 612 is then provided to a proportional-integral (“PI”) block 614, and then into an integration block 616 to generate a velocity vector command signal. The velocity vector command signal is then provided to a summing block 618 along with an actual velocity of a hoist 632 provided by an encoder 634. The summing block 618 provides an error representative of the difference between the commanded velocity and the actual velocity. The velocity vector error is then provided to PI block 620, which then provides an output to integration block 622, which in turn generates a position command. The position command is then provided to a summing block 624 along with an actual position of the hoist 632 provided by the encoder 634. The summing block 624 then generates an error between the commanded position and the actual position. The position error is then provided to a PI block 626, which then outputs a position command to a motor drive 628 of the hoist 632, which then controls a hoist motor 630.
Turning now to
The output of the force command block 652 is then summed with the actual force received from the force sensor 658 to generate a force error signal representative of a difference between the current force and the desired force at summing block 660. The output of the summing block 660 is provided to deadband module 662. Deadband module 662 is configured to determine whether the difference value output from the summing block 660 is within a deadband of the input values (i.e. is the difference sufficient to generate a response). The output from the deadband module 662 is provided to gain amplifier 664 along with the force command signal. The gain amplifier 664 also receives the force command signal. As stated above, in some instances, the force command is equivalent to the force applied by a load 665 (e.g., when the FLOAT mode is engaged). In one embodiment, the gain amplifier 664 dynamically amplifies the force error signal based on the force command signal being lifted. This amplification can thereby require a user to exert a greater force on the load in order for the load to move. The gain amplifier 664 provides the amplified output to a dynamic limit module 666.
The dynamic limit module 666 may be configured to limit the output of the gain amplifier 664 based on predetermined limit values. In one embodiment, the predetermined limit values are configured to prevent large changes from occurring where the force command may be substantially different than the actual force. The dynamic limit module 666 can dynamically limit a velocity vector command output. In one embodiment, the velocity vector command is dynamically limited to produce different maximum velocity commands according to the weight of the load 665 being lifted (e.g. the force command). As shown in
The output from the limit module 666 is a velocity vector command signal that is provided to a velocity summing module 668 along with an actual velocity vector value from an encoder 670 associated with a hoist system 672. The hoist system 672 may be configured as one of the hoist systems described herein. The output of the summing module 668 is provided to a proportional-integral (PI) control block 678. The PI control block 678 provides an output to an integrator module 680. In some embodiments, the PI control block 678 may be a proportional-integral-derivative (PID) control block. The integrator module 680 is configured to output a control signal to the motor drive 682, which is configured to control the hoist motor 684 based on the received control signal.
Turning now to
Turning now to
At process block 808, the controller 506 determines if there is a change in force associated with the load that exceeds a predetermined value. In some examples, the predetermined value is a static or user-settable value, such as five pounds. However, other values of more than five pounds or less than five pounds are also contemplated. In still other examples, the predetermined value may be a percentage of the load weight, such as 1%. However, values or more than 1% or less than 1% are contemplated. If a change in force does not exceed the predetermined value, the controller continues to monitor the load force at process block 806. Where the change in force does exceed the predetermined value, the controller then determines whether the force increased at process block 810. In response to determining that the force has increased, the controller 506 lowers the load at process block 812 as an increase in load is indicative of a user applying a downward force on the load.
In response to the force being determined to not have increased at process block 810, the controller 506 then determines that the force has decreased at process block 814. In response to determining that the force has decreased, the controller 506 raises the load at process block 816, as a decrease in load is indicative of a user applying an upward force on the load. Once the load is lowered at process block 812, or raised at process block 816, the controller 506 continues to monitor a load force at process block 806 to determine if any other changes to the load occur.
In some embodiments, the speed of the lowering and raising is proportional to the amount of downward and upward force sensed, respectively. For example, if an operator lightly pushes down on the load, the motor will slowly lower the load, while if the operator pushes down with more force, the load will be more quickly lowered. Similarly, if an operator lightly pushes upward on the load, the motor will slowly raise the load, while if the operator pushes upward on the load with more force, the load will be more quickly raise.
Turning now to
Turning now to
The sprocket 1206 is configured to ratchet multiple times per revolution of the hoist. The ratcheting of the sprocket 1206 is configured to hold the load if the motor and/or transmission were to fail and/or in a low power saving mode where the motor is relaxed to conserve battery or battery pack power. In some embodiments, the ratcheting mechanism within the sprocket 1206 can hold the load during a FLOAT mode, a static mode, or after a predetermined period of time has passed (e.g. 5 minutes) to reduce the strain on the drive motor 904 by allowing hoist pulley to rest on the ratcheting device. In some embodiments, a sensed or detected change in force applied to the zero-gravity chain hoist 900. In addition to removing strain from the drive motor 904, by allowing the hoist pulley to rest on the ratcheting device, power can be conserved, which can extend the life of a battery or battery pack in a battery or battery pack powered hoist as described herein.
Turning now to
Turning now to
The first remote control body 1400 includes an E-STOP input 1404, an UP input 1406, a down input 1408, and a FLOAT input 1410. The second remote control body 1402 also includes similar inputs. The second remote control body 1402 further includes an air hose connector 1412, and a load sensor 1414. As described above, the second remote control body 1402 may be linked into the lifting chain 1002 above a load hook to allow for the load sensors 1414 (e.g. load sensors 508 described above) to determine a load on the lifting chain 1002 indicative of the load being hoisted by the zero-gravity chain hoist 900.
Turning now to
Turning now to
Turning now to
To measure a deflection of the spring plate 1612, the first sensor 1614 induces an electrical signal on the surface of the first fixed conductive plate 1621 and the second sensor 1616 induces an electrical signal on the surface of the second fixed conductive plate 1622. However, it is contemplated that in some examples, the first sensor 1614 induces an electrical signal on the surface of the second fixed conductive plate 1622 and the second sensor 1616 induces an electrical signal on the surface of the first fixed conductive plate 1621. The sensors 1614, 1616 are, for example, able to output an electrical signal to the respective fixed conductive plates, which is then carried by the electrically conductive surface. The first sensor 1614 and the second sensor 1616 each include an antenna (e.g. a wireless sensor) configured to measure the electrical signals applied to the fixed conductive plates 1621, 1622. The antennas are configured to generate an output that varies with the distance between the first sensor 1614 and the first fixed conductive plate 1621 and the second sensor 1616 and the second fixed conductive plate 1622. The distance between the antenna and the conductive surface changes due to deflection of the spring plate 1612 in response to loading of the hoist, which in turn varies the distance between the sensors 1614, 1616 and the fixed conductive plates 1621, 1622. In one embodiment, the electrical output of the sensors 1614, 1616 is proportional to the distance between the fixed conductive plates 1621, 1622 and the antenna. In one embodiment, the sensors 1614, 1616 are electrically coupled to a sensor circuit 1618. The sensor circuit 1618 may include a tank circuit configured to determine a change in inductance and/or impedance detected by the antennas due to the deflection of the spring plate 1612.
As shown in
With reference to
The hoist 1804 is further coupled to a load cable 1808, which couples the hoist to a load 1810. Similar to the cable 1802, the load cable 1808 may be a wire cable, a rope, a chain, a hybrid, and the like. The hoist 1804 is configured to extend or retract the load cable 1808 in order to move the load 1810 in a longitudinal direction (e.g. up or down) along the load cable 1808. In some embodiments, the hoist 1804 includes an electric motor to extend or retract the load cable 1808. However, in other examples, mechanical winches or other mechanisms may be used.
The hoist system 1800 further includes a first load sensor 1812, and a second load sensor 1814. As shown in
In one example, as described above, in a FLOAT mode, the hoist may be controlled based on changes in the load, such as by a user manually applying a force to the load, in order to raise or lower the load using the hoist system. The load change detection system 1900 is configured to only allow for the load to move in a FLOAT mode when the change in load is within a certain range of values. As shown in
By only permitting operation of the hoist 1902 in a FLOAT mode when the change in load is within the predetermined range, the occurrence of unintended operations during float mode may be reduced. For example, if an object were to fall and come into contact with the load while the hoist 1902 is in the FLOAT mode, the load change detection system 1900 would prevent the object from causing the load to be lowered where the weight of the object is above a maximum force value 1904, such as those described above. Similarly, by having a minimum force value 1906, the hoist 1902 will not operate when the change in the load is below the minimum force value 1906. This may be useful where a user places a tool or other object on the load during operation. Provided the object weighs less than the minimum force value, the hoist 1902 will not allow the load to move when in a FLOAT operation.
In other embodiments, the hoist 1902 may further monitor the load for any sudden changes in the force input that may indicate an impact to the load. If the force increases or decreases too rapidly (e.g. exceeds predetermined thresholds), the hoist 1902 ceases operation to prevent movement of the load.
The above loading and speed values are for example purposes only, and it is contemplated that the hoist system can constantly update the maximum operating speed based on a detected load.
In the above example, in response to detecting a “hard” application of upward force to the load, the hoist system may continue to raise the load after the force is released by a second predetermined amount, which is greater than the first predetermined amount. In one embodiment, the “hard” application of upward force may be approximately 10 lbs of upward force. However, values of more than 10 lbs and less than 10 lbs are also contemplated. Further, the second predetermined value may be a distance such as 10 feet. However, distances of more than 10 feet or less than 10 feet are also contemplated. In other examples, the second predetermined value may be 10 seconds. However, values of more than 10 seconds and less than 10 seconds are also contemplated.
Turning now to
Turning now to
Other applications for a hoist system as described herein may include: holding a structure during demolition; removing demolition waste; hoisting commercial or personal components during maintenance; lifting construction components at a worksite; or other applications. It should be understood that the implementations and applications described herein are exemplary and should not be construed as limiting.
Thus, embodiments described herein provide, among other things, a zero-gravity hoist system. Various features and advantages are set forth in the following claims.
This application claims the benefit of, and priority to, U.S. Provisional Patent Application No. 62/965,574 filed Jan. 24, 2020; U.S. Provisional Patent Application No. 62/009,635, filed Apr. 14, 2020; U.S. Provisional Patent Application No. 63/044,783, filed Jun. 26, 2020; and U.S. Provisional Patent Application No. 63/092,715, filed Oct. 16, 2020, the entire contents of each are hereby incorporated by reference.
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