• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    A rotation stabilization device has an optical device (6), in particular a camera, and a position control device for the optical device (6). This optical device (6) is pivotable in a support frame (1) via at least one axis of rotation (7), which runs through the center of gravity of the optical device (6). To stabilize the optical device (6) are on the at least one axis of rotation (7) between an electric motor (3) and the optical device (6), a torque converter (10), the non-hopping the optical device (6) in any angular position stabilized or moved.
    公开号:AT516627A4
    申请号:T97/2015
    申请日:2015-02-23
    公开日:2016-07-15
    发明作者:Jens Ing Peters
    申请人:Peters Jens C Ing;
    IPC主号:
    专利说明:

    The invention relates to a rotation stabilization device having an optical device, in particular a camera, and a position control device for the optical device with a support frame, with at least one axis of rotation, which passes through the center of gravity of the optical device, with at least one body of revolution, wherein the optical device is pivotable via at least one rotary body, with at least one electric motor which drives a rotary body, with a device for determining the spatial orientation of the optical device, in particular a gyroscope, and with a control electronics, which controls the electric motor.
    The invention further relates to a method for operating such a rotation stabilization device.
    When broadcasting sporting events, documentaries, concerts, etc. increasingly remote-controlled cameras in moving suspensions, the camera cranes, ropes,
    Helicopters or multicopter are attached. There is a camera in a frame-like suspension.
    The camera is pivoted and stabilized by means of an electric motor along an axis. All known suspension forms have in common that the cameras used (including lens) are fixed so that the pan and tilt axis (possibly the rolling axes) of the cameras run through the center of gravity. This causes no torque forces to be applied to the camera. With intentional rotation thus only the moment of inertia of the camera and its support is overcome. The disadvantage, however, is that with a highly zoomed image section of the camera even the smallest disturbances on the holder can lead to an unstable image.
    It is also known that the optical device or the holder is stabilized via a control electronics with the aid of a position sensor (electric gyro = gyroscope) and a servomotor and kept constant. The disadvantage of such a purely mechanical coupling of the servomotor to the device to be stabilized can be seen by very rough gradients in motion sequences or in the angular stabilization. Especially with compensatory movements (caused by disturbance variables) for angle stabilization, only very small changes in the movement of the camera are necessary. At the beginning and at the end of each compensation movement, however, a sudden behavior in the movement of the servomotors can be detected.
    These erratic responses of the control to disturbances occur due to mechanical friction and mechanical tolerance in the components used. Since static friction is greater than sliding friction, the transition from the static friction zone to the sliding friction zone or back again leads to a sudden behavior during the transition.
    Furthermore, in many control applications, a servomotor with attached gear is used. However, many inexpensive transmission types have a so-called gear play, which turns out to be an insurmountable problem for continuous control. Any control movement in the opposite direction to the last movement must overcome this backlash and therefore acts too late or too vigorously on the control deviation.
    The invention has for its object to provide a stabilization device for the camera, eliminating the mechanical influences of the type described above on the control behavior.
    This object is achieved according to the invention with a device having the features of claim 1.
    Furthermore, this object is achieved by a method having the features of claim 14.
    Preferred and advantageous embodiments of the invention are subject of the dependent claims.
    According to the invention, a torque converter is arranged on the rotational body driven by the electric motor between the electric motor and the optical device, and the position of the optical device is regulated by a torque converter arranged between the electric motor and the optical device on the rotary body driven by the electric motor. Thus it is achieved that each control response to disturbances without collision or jump occurs. Resulting compensation movements on the optical device are extremely precise and subject to only uniform accelerations or delays with smooth transitions. The optical device can therefore be stabilized in a certain angular position and kept constant, the disturbances are compensated.
    In the context of the invention, optical device is preferably understood to mean a device for recording and / or reproducing images, in particular a camera.
    In a preferred embodiment of the invention, it is provided that a torque converter is a rotational damper, in particular a hydrodynamic torque converter.
    This can consist of a drum-shaped, closed housing, which is filled with a high-viscosity oil. Into the drum leads centrally a sealed drive shaft, which is driven at one end by an electric motor. At the other end of the drive shaft is located in the drum a paddle wheel. This paddle wheel is free to rotate in the oil-filled drum housing and, when driven externally via the drive shaft, will attempt to rotate the drum-shaped housing in the same direction due to the high viscosity of the oil.
    In a further embodiment of the invention, a further rotational body, in particular a shaft, is arranged on the torque converter on a side of the torque converter not facing the electric motor, in particular on the side opposite the electric motor. On this rotation body, the torque that is transmitted to the inside of the paddle wheel via the oil to the drum, is derived. The torque with which the drum is taken, is dependent on the speed of the paddle wheel in a wide range.
    In the context of the invention, it can be provided that the additional rotary body arranged on the torque converter is a connecting piece between the torque converter and the optical device, in particular that the further rotary body arranged on the torque converter is connected to the optical device or to a holder of the optical device. About the torque transmitted from the drum housing to the rotary body, the holder is rotated or pivoted about the axis of rotation of the rotary body.
    In a further advantageous embodiment of the invention, it is provided that the further rotational body arranged on the torque converter and optionally the rotational body driven by the electric motor are arranged on the rotational axis. This arrangement of components prevents a possible clearance from being created by using additional force-transmitting components.
    A further embodiment provides that the carrier frame has a recess, in particular a bore, and that the further rotational body arranged on the torque converter is guided through a recess of the carrier frame. This embodiment is intended to ensure that the axis of rotation preferably passes through the center of gravity of the device, or as close as possible thereto.
    It is preferably provided that the optical device can be pivoted via the further rotational body arranged on the torque converter. The optical device can thus be pivoted and aligned on the axis of rotation by 360 °.
    A particularly preferred embodiment of the invention provides that in each case a torque converter is provided on two opposite sides of the optical device.
    The mechanical arrangement of the two units, each consisting of a motor and a torque converter, allows either the two motors to rotate in the same direction of rotation or one to rotate in opposite directions to the other. Since both units acting on one axle are braced against each other by the opposite rotation, the torque converter also acts as a damper at the same time. The unit can therefore also be referred to as a motor / rotary damper unit.
    In the context of the invention it is provided that a device for determining the spatial orientation of the optical device is arranged on the optical device or on a holder of the optical device, and that a control technique controls the electric motor via the device for determining the spatial orientation of the optical device or controls. The orientation of the spatial orientation is preferably determined by means of a gyroscope. Since the optical device is to be moved or swiveled, position coordinates of the optical device are decisive.
    In a further embodiment of the invention, the electric motor has a holder, wherein the holder of the electric motor, and optionally the control electronics, is connected to the carrier frame. To hold the electric motor statically in position, this is arranged on the support frame. The control electronics are also located on
    Carrier frame, so as not to move unnecessary mass when pivoting the optical device with.
    In the context of the invention it can be provided that an axis of rotation extends substantially horizontally in the operating state of the rotational stabilization device. Furthermore, it can be provided that a further axis of rotation in the operating state of the rotational stabilization device is aligned substantially perpendicularly. Furthermore, it is preferred if the axis of rotation or the axes of rotation run or run through the center of gravity of the rotational stabilization device. It is particularly preferred if the center of gravity of the optical device is equal to the center of gravity of the rotation stabilization device. By provided in a [referred embodiment, normally successive, extending through the center of gravity rotation axis, only the moment of inertia must be overcome by the motor / rotary damper units in a rotation. In this preferred embodiment, very little to no deviation moments occur.
    In a particularly preferred embodiment of the method according to the invention it is provided that the position of the optical device is controlled such that the profile of the torque transmitted by the torque converter in a control range is substantially linear to its speed, and that the rotation stabilizing device linear in this control range is moved in rotation. The linearity between the speed and torque converter torques results in uniform movements of the optical device. However, the linear course of the so-called output torque of the torque converter is given only up to a typical construction limit speed. However, this regulation avoids non-linear areas. Operation always takes place below the above-mentioned limit speed, where the relationship between speed and output torque is largely linear. As a particular advantage occur no erratic movements, as occurs for example in motion sequences with actuators.
    A further embodiment of the invention consists in that the position of the optical device is regulated by two torque converters arranged on opposite sides of the optical device, from each of which a further rotational body runs on the axis of rotation. To control the optical device is provided that the two torque converter driven in the same direction or in the same direction and / or that the two torque converter are driven at the same or different speed. The torque converter are particularly preferably on the same axis of rotation. By this arrangement and regulation of the torque converter, a stabilization of the axis or the optical device is achieved. A stabilization or a persistence of the axle in a desired position can then occur when the two arranged on an axis opposite engine / rotary damper with the same moment but opposite to rotate.
    In the context of the invention, it may be provided that the rotation about the rotation axes comes to a standstill when the rotational motion of the torque converters is the same, if the torques of the torque converters are the same or the sum of the opposing torques is zero. Furthermore, it can be provided that the rotation about the rotation axes takes place in the case of opposite rotational movement of the torque converter only if the sum of the torques is not equal to zero, wherein the sum of the torques can have a positive or negative value. In order to deflect the rotary shaft, the speed of the electric motors must be controlled in such a way that a differential torque arises from the counter-rotating torque converters. In the direction in which the moment is greater, a rotational movement is effected. The speed of the rotation depends on the size of the moment difference. Stabilization is only possible again when the opposing torques are equal again or the difference of the moments is zero again.
    A preferred embodiment provides that the torque transmission from the electric motor to the torque converter takes place in the region of the sliding friction, wherein in particular the changes in the torque transmitted by the torque converter to the optical device in the region of the sliding friction are linear. When the rotation shaft is stationary, the paddle wheels in the drum of the torque converter rotate in opposite directions with a difference torque of zero. These paddle wheels are thus in the range of sliding friction. For smallest changes in the differential moments, the drive axle is thus moved with a linear rotation (no occurrence of a jump) of the torque converter. Furthermore, the movement axis is in the clamped state by the opposite rotational movement. In a possible use of a transmission for power transmission thus a gear play is canceled. For larger deviations, both motors work together (direction of rotation in the same direction) and the moments of the torque converter add up and are correspondingly large.
    Advantages of a unit consisting of an electric motor and a torque converter over a conventional axle stabilization with a servomotor are: • With a differential torque equal to zero of counter rotating torque converters, there is no stiction and no possible backlash. • The torque curve can be continuously adjusted from zero to maximum in a flat control line. • When adjusting a larger deviation from the setpoint, one of the two motor / damper axes must reverse the direction of rotation. The occurring transition from static friction to sliding friction and overcoming the gear play are damped by the already running in the correct direction of rotation first strand. The associated nonlinearity in the torque curve is therefore small.
    Further features and advantages of the invention will become apparent from the following description of a preferred embodiment of the invention with reference to the accompanying drawings.
    It shows:
    1 shows a schematic structure of a known camera stabilization,
    2 shows a schematic representation of an embodiment of a device according to the invention,
    Fig. 3 is a diagram of a torque curve in
    Dependent on the speed of a torque converter, and FIG. 4 shows an illustration of a torque curve as a function of the control deviation.
    In Fig. 1, the schematic structure of a known camera stabilization is shown. On a support frame 1, a control electronics 2 and an electric motor 3 is arranged. Via a rotary body 4, which passes through the support frame 1, the torque of the electric motor 3 is transmitted to a holder 5. On the holder 5, an optical device 6 is arranged, which is pivotable about a horizontal axis of rotation 7. In Fig. 1, the optical device 6 is a camera. The axis of the rotary body 4 runs with the axis of rotation 7 through the center of gravity of the optical device 6. Thus, only the moment of inertia of the elements to be rotated need be overcome. In order to control the electric motor 3 via the control electronics 2, a gyroscope 8 for determining the position of the optical device 6 is provided.
    In Fig. 2 is an embodiment of an inventive
    Device shown schematically, which is basically similar to the device described for Fig. 1 is constructed. In contrast to the apparatus shown in FIG. 1, the device according to the invention shown has on both sides of the support frame 1 in each case an electric motor 3, which in each case drives a rotation body 9. Between the electric motors 3 and the optical device 6, a respective torque converter 10 is arranged on the rotary body 9 driven by the electric motor 3. Starting from the torque converters 10, in each case a further rotary body 11 is arranged in the direction of the optical device 6, which extends through a recess in the carrier frame 1 and is connected to the holder 5, whereby the optical device 6 can be pivoted about the axis of rotation 7.
    Due to a better overview, a device which is only pivotable about a horizontal axis of rotation 7 is shown. In other embodiments, the device can also be pivoted via further axes of rotation, for example via a vertical axis of rotation or via a further horizontal axis of rotation, which runs in particular perpendicular to the axis of rotation 7. The axis of rotation 7 extends through the center of gravity of the rotation stabilizing device and is congruent with the axes of the rotary bodies 9, 11.
    In FIG. 3, the curve of the torque of a torque converter 10 is shown as a function of the rotational speed. It can be seen that in a large range, the torque is linear to the speed. Only in the last third does the moment asymptotically approach a constant maximum value. This maximum value is typical of a building. To control or stabilize the position of the optical device 6 is preferably controlled only in the range of linear dependence between speed and torque.
    In Fig. 4 is a linear torque curve in
    Dependence on control deviation shown in degrees [°]. The mechanical arrangement of the two units of electric motor 3 and torque converter 10 allows either both electric motors 3 can rotate in the same direction or each one can rotate in opposite directions to the other, and this for each electric motor 3, each with different speeds. The diagram illustrates with which torque (= depending on the speed) for positive or negative deviations the units of electric motor 3 and torque converter 10 should react to it. The slopes of the two motor / rotary damper lines 12, 13 and the straight line 14 with the summation torque are assumed in the diagram and represent only an example of a control setting. It is essential that the two torques always equal at zero deviation, but in opposite directions Own amount, ie the two torques cancel each other out in this point.
    The peculiarity in the use of a combination of electric motor 3 and torque converter 10 is the ability to operate the electric motors 3 even when the output of the associated torque converter 10 is blocked. This blocking is achieved in that the second combination of electric motor 3 and torque converter 10 operates at the same but opposite rotational speed against the first combination.
    For small control deviation values (in the diagram between 0 ° to + 5 ° or 0 ° to -5 °), the directions of rotation of the two units of electric motor 3 and torque converter 10 are in opposite directions and thus only the differential torque acts on the rotary body 11. For larger deviations, the electric motors 3 work together (direction of rotation in the same direction) and the torque converter 10 moments add up and are therefore correspondingly large.
    But this also means that at zero (i.e.
    Control deviation exists = bracket 5 is correct) both servomotors 3 continue to rotate in opposite directions with the same (low) speed. The differential torque is zero and therefore the rotary body 11 or the optical device 6 is stationary when the motors are running. The rotating body 11 including the two units are still braced to each other, a gear game thus repealed. Due to the continuous rotation of the paddle wheels in the interior of the torque converter 10, the static friction is already overcome and there is the state of sliding friction. Therefore, with a renewed adjustment of a deviation, no stiction and no gear game to overcome.
    权利要求:
    Claims (20)
    [1]
    claims:
    1. Rotation stabilization device with an optical device (6), in particular a camera, and a position control device for the optical device (6) with a support frame (1), with at least one axis of rotation (7), which by the center of gravity of the optical device ( 6), with at least one rotary body (9, 11), wherein the optical device (6) via at least one rotary body (11) is pivotable, with at least one electric motor (3) having a rotary body (9), in particular a shaft, drives, with a device for determining the spatial orientation of the optical device (6), in particular a gyroscope (8), and with a control electronics (2) which controls the electric motor (3), characterized in that between the electric motor (3) and the optical device (6) is arranged a torque converter (10) on the rotary body (9) driven by the electric motor (3).
    [2]
    2. rotation stabilization device according to claim 1, characterized in that the torque converter (10) is a rotational damper, in particular a hydrodynamic torque converter.
    [3]
    3. rotation stabilization device according to claim 1 or 2, characterized in that at a not to the electric motor (3) facing side of the torque converter (10), in particular on the electric motor (3) opposite side, another rotational body (11), in particular a shaft is arranged on the torque converter (10).
    [4]
    4. rotation stabilization device according to one of claims 1 to 3, characterized in that the torque converter (10) arranged further rotational body (11) is a connecting piece between the torque converter (10) and the optical device (6), in particular that of the Torque converter (10) arranged further rotational body (11) with the optical device (6) or with a holder (5) of the optical device (6) is connected.
    [5]
    5. Rotation stabilizing device according to one of claims 1 to 4, characterized in that arranged on the torque converter (10), further rotational body (11) and optionally of the electric motor (3) driven rotary body (9) arranged on the rotation axis (7) is.
    [6]
    6. rotation stabilization device according to one of claims 1 to 5, characterized in that the support frame (1) has a recess, in particular a bore, and that the torque converter (10) arranged further rotational body (11) is guided through the recess ,
    [7]
    7. rotation stabilization device according to one of claims 1 to 6, characterized in that the optical device (6) via the torque converter (10) arranged further rotary body (11) is pivotable.
    [8]
    8. rotation stabilization device according to one of claims 1 to 7, characterized in that on two opposite sides of the optical device (6) each have a torque converter (10) is provided.
    [9]
    9. rotation stabilization device according to one of claims 1 to 8, characterized in that the means for determining the spatial orientation of the optical device (6) on the optical device (6) or on a holder (5) of the optical device (6). is arranged and that the control technology (2) controls the electric motor (3) via the means for determining the spatial orientation of the optical device (6) or controls.
    [10]
    10. Rotation stabilizing device according to one of claims 1 to 9, characterized in that the electric motor (3) has a holder, and that the holder of the electric motor (3), and optionally the control electronics (2), with the support frame (1). connected is.
    [11]
    11. Rotation stabilization device according to one of claims 1 to 10, characterized in that a rotation axis (7) in the use state of the rotation stabilization device is substantially horizontal and / or that a rotation axis in the use state of the rotation stabilization device is aligned substantially perpendicular.
    [12]
    12. rotation stabilization device according to one of claims 1 to 11, characterized in that the axis of rotation (7) or the axes of rotation passes through the center of gravity of the rotation stabilization device or extend.
    [13]
    13. Rotation stabilizer according to one of claims 1 to 12, characterized in that the center of gravity of the optical device (6) is equal to the center of gravity of the rotation stabilizing device.
    [14]
    14. A method for operating a rotation stabilization device with an optical device (6), in particular a camera, and a position control device for the optical device (6) with a support frame (1), with at least one axis of rotation (7), which by the center of gravity the optical device (6) extends, with at least one rotary body (9, 11), wherein the optical device (6) is pivotable via at least one rotary body (11), with at least one electric motor (3) having a rotary body (9), in particular a shaft, drives, with a device for determining the spatial orientation of the optical device (6), in particular a gyroscope (8), and with a control electronics (2) which controls the electric motor (3), characterized in that the position the optical device (6) by a rotating body driven by the electric motor (3) between the electric motor (3) and the optical device (6) (9) arranged torque converter (10) is controlled.
    [15]
    15. The method according to claim 14, characterized in that the position of the optical device (6) is controlled such that the profile of the torque converter (10) transmitted torque in a control range is substantially linear to its speed and that in this control range Rotation stabilization device is moved linearly rotationally.
    [16]
    16. The method according to claim 14 or 15, characterized in that the position of the optical device (6) by two on opposite sides of the optical device (6) arranged torque converter (10) is controlled, of which from each of a further rotary body (11) on the axis of rotation (7).
    [17]
    17. The method according to claim 16, characterized in that the two torque converter (10) are driven in the same or in the same direction and / or with the same or different rotational speed.
    [18]
    18. The method according to claim 16 or 17, characterized in that the rotation about the axis of rotation (7) at the same rotational movement of the torque converter (10) comes to a standstill when the torques of the torque converter (10) are equal or the sum of the gegengleichen Torque is zero.
    [19]
    19. The method according to claim 17 or 18, characterized in that the rotation about the axis of rotation (7) takes place at the same rotational movement of the torque converter (10) when the sum of the torques is not equal to zero.
    [20]
    20. The method according to any one of claims 17 to 19, characterized in that the torque transmission from the electric motor (3) to the torque converter (10) takes place in the region of the sliding friction, in particular that the changes of the torque converter (10) to the optical device (6 ) transmitted torque in the field of sliding friction linear.
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    同族专利:
    公开号 | 公开日
    AT516627B1|2016-07-15|
    WO2016134388A1|2016-09-01|
    US20180038544A1|2018-02-08|
    EP3262333A1|2018-01-03|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    WO2011140245A1|2010-05-04|2011-11-10|Chapman/Leonard Studio Equipment, Inc.|Camera head|
    DE102010054603A1|2010-12-15|2012-06-21|Emt Ingenieurgesellschaft Dipl.-Ing. Hartmut Euer Mbh|Electro-mechanical angular position control device for position-stabilized camera platforms, has stator that is provided with smooth soft magnetic ring for guiding magnetic flux generated by angle sensor|
    US20140288694A1|2011-11-02|2014-09-25|Brown Garrett W|Actively stabilized payload support apparatus and methods|
    GB2282863B|1993-10-14|1997-06-18|Vinten Group Plc|Improvements in or relating to apparatus mountings providing at least one axis of movement with damping|
    US7036777B2|2003-05-14|2006-05-02|Quickset International, Inc.|Zero backlash positioning device|
    US7642741B2|2005-04-27|2010-01-05|Sidman Adam D|Handheld platform stabilization system employing distributed rotation sensors|
    DE102008039468A1|2008-08-25|2010-03-04|Stefan Reich|Device and method for stabilizing the position of cameras|
    DE102012203834B3|2012-03-12|2013-06-06|Deutsches Zentrum für Luft- und Raumfahrt e.V.|Camera stabilization system for stabilizing camera at flight robot or vehicle, has spinning devices associated to rotational axis of rotation drives, where rotational torques of rotation drives are supported on spinning devices|
    US9154673B2|2013-02-04|2015-10-06|Kenneth Stone|Cable camera systems and methods|CN106641617B|2016-11-22|2019-02-05|魏承赟|A kind of photographic stabilizer|
    US10564527B2|2018-04-09|2020-02-18|Francis Kenny|Device and system for maintaining a level horizon of a supported camera|
    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    ATA97/2015A|AT516627B1|2015-02-23|2015-02-23|Rotation stabilizing device|ATA97/2015A| AT516627B1|2015-02-23|2015-02-23|Rotation stabilizing device|
    PCT/AT2016/000008| WO2016134388A1|2015-02-23|2016-02-04|Rotation stabilization device|
    US15/552,414| US20180038544A1|2015-02-23|2016-02-04|Rotation stabilization device|
    EP16706511.9A| EP3262333A1|2015-02-23|2016-02-04|Rotation stabilization device|
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