Patent Application
20240344556
The present application claims the priority of Chinese patent application No. 202111276082.9 entitled “Balance Bearing Device and Control Method Thereof” and filed on Oct. 29, 2021, which is incorporated herein in its entirety by reference.
The present application relates to the technical field of transportation technology, in particular to a balance bearing device and a control method thereof, and a transport equipment.
Transport equipment has a wide range of usage, and can transport a component to be transported from location A to location B according to requirements. If the component to be transported experiences tilting or other conditions during transport, the safety of the component to be transported will be affected.
Taking the field of wind power technology as an example, the constituent parts of the wind turbine currently need to be transported according to the predetermined construction area of the wind turbine. During transport, it is necessary to ensure the balance of the components and keep them in a horizontal state. During the transport of the offshore wind turbine, due to the surge of seawater, the components are prone to losing balance or even tipping over during transport.
Therefore, there is an urgent need for a balance bearing device.
Embodiments of the present application provide a balance bearing device and a control method thereof, and a transport equipment. The balance bearing device can meet the balance requirements of the component to be transported.
In one aspect, the embodiments of the present application provide a balanced load-bearing device for a transport equipment, including two or more mobile assemblies, the two or more mobile assemblies being arranged to be stacked, each mobile assembly including a base, a mobile component, and an adjusting component. The base has an arc-shaped guide rail, and the mobile component is arranged on the base and is able to move along the extension trajectory of the guide rail under the action of gravity. The adjusting component is connected between the mobile component and the base, and is configured to limit the limiting position of the mobile component moving along the guide rail; wherein the extension directions of the guide rails of two adjacent mobile assemblies intersect with each other, and the base of one of the two adjacent mobile assemblies is connected to the mobile component of the other. In the stacking direction of two or more mobile assemblies, the mobile assembly at the topmost layer is able to be connected to the component to be transported through the mobile component.
According to one aspect of the embodiments of the present application, the mobile component includes a bearing body and multiple mobile units. The multiple mobile units are distributed to be spaced apart and connected to the bearing body respectively. Each mobile unit is movably connected to the guide rail.
According to one aspect of the embodiments of the present application, the base of each mobile assembly has two or more parallel guide rails which are arranged to be spaced apart, and each guide rail is movably connected to at least one mobile unit.
According to one aspect of the embodiments of the present application, the mobile unit includes a support frame, a traveling component, and a locking component. The traveling component is connected to the support frame through the locking component, and the traveling component is able to move along the extension trajectory of the guide rail. The locking component is used to lock the position of the traveling component on the base.
According to one aspect of the embodiments of the present application, in the stacking direction, the base has a top surface and a bottom surface which are arranged to be opposite to each other. The top surface is an arc-shaped surface protruding toward a direction where the bottom surface is located. The guide rail is arranged on the arc-shaped surface. The traveling component is at least partially supported on the top surface, and one of the traveling components and the guide rail is at least partially extended into the interior of the other and can be movably connected to the other.
According to one aspect of the embodiments of the present application, the guide rail is an arc-shaped groove body and is formed to be recessed from the top surface toward a side close to the bottom surface. The traveling component includes a traveling wheel and a clamping protrusion rotatably connected to the traveling wheel. The traveling wheel is supported on the top surface and rotatably connected to the locking component. The clamping protrusion is clamped inside the guide rail and is able to move along the extension direction of the guide rail.
According to one aspect of the embodiments of the present application, the guide rail is an arc-shaped protrusion and is formed to protrude from the top surface toward the side away from the bottom surface. The traveling component includes a traveling wheel and a clamping groove arranged on the traveling wheel. The traveling wheel is supported on the top surface, and the clamping groove is clamped to the guide rail and is able to move along the extension direction of the guide rail.
According to one aspect of the embodiments of the present application, the locking component includes an installation body and a rotating body. The installation body is connected to the support frame. The rotating body is rotatably connected to the installation body through a first rotating pair, and the traveling component is rotatably connected to the rotating body through a second rotating pair. The rotational axis of the first rotating pair is parallel to the rotational axis of the second rotating pair and spaced apart from the rotational axis of the second rotating pair.
According to one aspect of the embodiments of the present application, the rotating body includes a first rotating body and a second rotating body. The installation body is located between the first rotating body and the second rotating body. The first rotating pair is fixedly connected to the first rotating body and the second rotating body and is rotatably connected to the installation body. The traveling component is connected to the first rotating body.
According to one aspect of the embodiments of the present application, the locking component further includes a driving assembly which drives the rotating body to rotate relative to the installation body with the first rotating pair as the rotation center.
According to one aspect of the embodiments of the present application, the driving assembly includes an adjusting screw and a nut. One end of the adjusting screw is connected to the base and the other end passes through the first rotating body. The nut is in threaded connection with the adjusting screw. The nut is able to move along the axial direction of the adjusting screw and squeeze the first rotating body so as to drive the rotating body as a whole to rotate relative to the installation body with the first rotating pair as the center.
According to one aspect of the embodiments of the present application, the driving assembly includes an electric driving component, one end of which is connected to a support frame and the other end of which is engaged with a second rotating body, so as to drive the rotating body as a whole to rotate relative to the installation body with the first rotating pair as the center.
According to one aspect of the embodiments of the present application, the electric drive component includes a telescopic member which is connected to a second rotating body. The telescopic member extends or retracts to drive the second rotating body to rotate the first rotating body and the traveling component with the first rotating pair as a center.
According to one aspect of the embodiments of the present application, the locking component further includes an insertion part which can be detachably connected to the traveling component, the installation body, and the rotating body.
According to one aspect of the embodiments of the present application, the number of traveling components is multiple, and each traveling component is correspondingly provided with a locking component.
According to one aspect of the embodiments of the present application, the balanced bearing device further includes an adapter assembly, and the adapter assembly is connected between two adjacent mobile assemblies.
According to one aspect of the embodiments of the present application, the adapter assembly includes a transition platform and a support rod. The transition platform is located between two adjacent mobile assemblies, and an arc-shaped guide groove is provided on the base of one of the adjacent mobile assemblies. The transition platform is connected to the mobile component of one of the two adjacent mobile assemblies and is connected to the base of the other. One end of the support rod is hinged with the transition platform and the other end is movably connected to the arc-shaped guide groove.
According to one aspect of the embodiments of the present application, the adjusting component includes a telescopic cylinder. One of a cylinder body and a cylinder rod of the telescopic cylinder is connected to the mobile component and the other is connected to the base.
According to one aspect of the embodiments of the present application, the adjusting component includes an elastic body, one end of which is connected to the mobile component and the other end is connected to the base.
According to one aspect of the embodiments of the present application, the adjusting component includes an electromagnetic component which includes a first electromagnetic part and a second electromagnetic part. The first electromagnetic part is connected to the mobile component, and the second electromagnetic part is connected to the base. The first electromagnetic part and the second electromagnetic part are able to interact with each other and generate an action of magnetic force.
According to one aspect of the embodiments of the present application, the number of mobile assemblies is two, and the extension trajectories of the guide rails of the two mobile assemblies are perpendicular to each other.
According to one aspect of the embodiments of the present application, the balance bearing device further includes a detector and a controller. The detector is configured to detect the tilting condition of the transport equipment. The controller is configured so that when the tilting condition is within the preset threshold range, the respective mobile component is able to be kept moving along the guide rail under the action of gravity so that the mobile component for connection with the component to be transported is in the balance position.
According to one aspect of the embodiments of the present application, the tilting condition includes the inclination angle A of the transport equipment relative to the horizontal plane, and the preset threshold range includes −7°±0.5°≤A≤7°±0.5°.
According to one aspect of the embodiments of the present application, the tilting condition further includes the displacement B of the mobile component along the extension direction of the corresponding guide rail. The preset threshold range further includes B1−B2≤B≤B1+B2, where B1 is the length dimension of the adjusting component in the extension direction of the guide rail when the center of gravity of the mobile component of the mobile assembly for connection with the component to be transported coincides with the center of gravity of the base in the stacking direction, and B2 is the offset dimension of the center of gravity of the mobile component of the mobile assembly for connection with the component to be transported relative to the center of gravity of the base, in the extension direction of the guide rail when the inclination angle A of the transport equipment reaches the preset threshold range.
According to one aspect of the embodiments of the present application, the controller is further configured to control the adjusting component to provide a force opposite to the direction of movement of the mobile component to the mobile component, and/or to lock the position of the mobile component of each mobile assembly relative to the base, when the tilting condition exceeds a preset threshold range.
In another aspect, the embodiment of the present application further provides a control method for a balance bearing device, including:
According to another aspect of the embodiments of the present application, the control method further includes: when the tilting condition exceeds a preset threshold range, the adjusting component is controlled to provide a force opposite to the direction of movement of the mobile component to the mobile component, and/or to lock the position of the mobile component of each mobile assembly relative to the base.
In still another aspect, the embodiments of the present application further provides a transport equipment, which includes a balance bearing device as described in any of the above.
According to the balance bearing device and its control method, as well as the transport equipment provided in the embodiments of the present application, the balance bearing device can be placed on transport vehicles, transport ships, and other transport equipment. The balance bearing device includes two or more mobile assemblies which are arranged to be stacked, and each mobile assembly includes a base, a mobile component and an adjusting component. The extension directions of the guide rails of two adjacent mobile assemblies intersect with each other, and the base of one of the two adjacent mobile assemblies is connected to the mobile component of the other. In transporting the component to be transported, in the stacking direction of two or more mobile assemblies, the mobile component at the topmost layer is connected to the component to be transported through the mobile component. Due to the arc-shaped guide rail of the base, the mobile component is arranged on the base and can move along the extension trajectory of the guide rail, so that when the transport equipment tilts, the corresponding mobile component can move along the extension trajectory of the corresponding guide rail under the action of gravity, so that the mobile component for connection with the component to be transported are always in a balance position, which facilitates the control. The adjusting component which is disposed correspondingly can limit the limiting position of the mobile component moving along the guide rail, which avoids separation of the mobile component from the base, ensures transport safety, and can be suitable for the transport of the components under unstable conditions such as on the sea.
The following will refer to the accompanying drawings to describe the features, advantages, and technical effects of the exemplary embodiments of the present application.
Wherein:
In the attached drawings, the same components are marked with the same reference sign. The attached drawings were not drawn to the actual scale.
The following will provide a detailed description of the features and exemplary embodiments of the present application in various aspects. In the detailed description below, many specific details are proposed to provide a comprehensive understanding of the present application. However, it is evident to those skilled in the art that the present application can be implemented without the need for some of these specific details. The description of the embodiments below is only intended to provide a better understanding of the present application by showing examples of the present application. In the accompanying drawings and the following description, at least some well-known structures and techniques are not shown in order to avoid unnecessary ambiguity to the present application; Moreover, for clarity, the dimensions of some structures may have been exaggerated. In addition, the features, structures, or characteristics described below can be combined in one or more embodiments in any suitable manner.
The directional words appearing in the following description are all the directions shown in the figures, and are not intended to limit the specific structure of the balance bearing device, the control method thereof and the transport equipment in the present application. In the description of the present application, it should also be noted that unless otherwise specified and limited, the terms “installation” and “connection” should be broadly understood, for example, it can be fixed connection, detachable connection, or integrated connection; It can be direct connection or indirect connection. For the skilled person in the art, the specific meanings of the above terms in the present application can be understood according to specific circumstances.
At present, the constituent parts of the wind turbine need to be transported according to the predetermined construction area of the wind turbine. During transport, it is necessary to ensure the balance of the components and keep them in a horizontal state. Especially for the transportation of the offshore wind turbine, due to transportation costs and water depth in the sea area, the current offshore wind turbine transport ship is relatively small. Therefore, during the installation and lifting process of the offshore wind turbine, due to the shaking of the transport ship, the main engine and other components lose balance, leading to safety risks or extending the lifting time from the transport ship, which cannot achieve and ensure efficient lifting of the offshore wind turbine, and greatly increases the installation cost of the wind turbine.
The existing solutions usually use a six degree-of-freedom robotic arm for compensate a six degree-of-freedom control. The control manner is relatively complex, it is difficult to balance and adjust, and the cost is high.
To address the above issues, the embodiments of the present application provide a balance bearing device that can meet the balancing need of the component to be transported, has a low cost and facilitates the control.
In order to better understand the present application, a detailed description of the balance bearing device, its control method, and transport equipment according to the embodiments of the present application will be provided below, in conjunction with
Please refer to
Optionally, the number of mobile assemblies 1 is not limited specifically and can be two, three, or even more.
Optionally, in respective mobile assembly 1, the extension directions X of the guide rails 11 on the bases 10 of any two mobile assemblies 1 intersect with each other.
Optionally, in the stacking direction Y, the arc-shaped guide rail 11 on the base 10 of the mobile assembly 1 located at the top layer is recessed towards the direction of the mobile assembly 1 located at the bottom layer. In the stacking direction Y, the arc-shaped guide rails 11 of respective mobile assembly 1 are recessed along the same direction, and all recessed towards the side where the mobile assembly 1 at the bottom layer is located. The arc-shaped guide rail 11 can be the guide rail 11 of the circular arc or the guide rail 11 of the elliptical arc.
The mobile assembly 1 located at the topmost layer can be the mobile assembly 1 provided farthest away from the transport equipment 200 in the stacking direction Y when the balance bearing device 100 is placed on the transport equipment 200 to operate.
The balance bearing device 100 provided in the embodiment of this application can be installed on the transport equipment 200 such as transport vehicle and transport ship when in use. The balance bearing device 100 includes two or more stacked mobile assembly 1, each of which includes a base 10, a mobile component 20 and an adjusting component 30. The extension directions X of the guide rails 11 of the adjacent two mobile assemblies 1 are arranged to intersect with each other, and the base 10 of one of the mobile assemblies 1 is connected to the mobile component 20 of the other. In transporting the component 300 to be transported, it is possible to connect the mobile assembly 1 at the topmost layer in the stacking direction Y of two or more mobile assemblies 1 to the component 300 to be transported through the mobile component 20. Due to the arc-shaped guide rail 11 of the base 10, the mobile component 20 is provided on the base 10 and can move along the extension trajectory of the guide rail 11, so that when the transport equipment 200 tilts, the corresponding mobile component 20 can move along the extension trajectory of the corresponding guide rail 11 under gravity so that the mobile component 20 connected to the component 300 to be transported is always in a balance position, which facilitates control. The corresponding adjusting component 30 can limit the limiting position of the mobile component 20 moving along the guide rail 11, avoiding separation of the mobile component 20 from the base 10, ensuring transport safety on the basis of meeting the balance requirements of the component 300 to be transported, thereby being suitable for the transport of components under unstable conditions such as on the sea.
At the same time, due to the number of mobile assemblies 1 being two or more, the extension directions X of the guide rails 11 of the adjacent two mobile assemblies 1 are arranged to intersect with each other, and the base 10 of one of the mobile assemblies is connected to the mobile component 20 of the other of the mobile assemblies, which can adapt to the tilt of the transport equipment 200 in different directions. Moreover, the mobile assembly 1 has a simple structure and has a modular design, which can reduce the overall cost of the balance bearing device 100.
Please refer to
In the balance bearing device 100 provided in the embodiments of the present application, the mobile component 1 adopts the above structural form, which can ensure the requirements of the connection with the component 300 to be transported and the requirements of the connection between the adjacent two mobile assemblies 1. Meanwhile, the mobile component 1 can engage with the corresponding guide rail 11 through multiple mobile units 22, so that when the transport equipment 200 shakes and loses balance, the mobile component 20 can drive adjacent mobile assembly 1 connected therewith or the component 300 to be transported to move along the corresponding guide rail 11 under the action of gravity, ensuring the balance requirements of the component 300 to be transported.
Optionally, the bearing body 21 can be a solid seat structure, of course, can also be hollow frame structure. A connection interface can be provided on the bearing body 21 to facilitate connection with the component 300 to be transported or the base 10 of the adjacent bearing assembly.
Optionally, the number of mobile units 22 can be two, three, or even more. Alternatively, the mobile units 22 are arranged in pairs, and the paired mobile units 22 are symmetrically distributed on the bearing body 21 to ensure the force balance of the bearing body and further ensure the transport safety.
In some optional embodiments, the balance bearing device 100 provided in the embodiments of the present application further includes an adapter assembly 2, which is connected between two adjacent mobile assemblies 1. That is to say, two adjacent mobile assemblies 1 are indirectly connected to each other through the adapter component 2, which facilitates the connection requirement between the two adjacent mobile assemblies 1.
As an optional implementation, in the balance bearing device 100 provided in the present embodiments of the application, the adapter component 2 includes a transition platform 201 and a support rod 202. The transition platform 201 is located between adjacent two mobile assemblies 1, and an arc-shaped guide groove 14 is provided on the base 10 of one of the adjacent two mobile assemblies 1. The transition platform 201 is connected to the mobile component 20 of one of the adjacent two mobile assemblies 1 and is connected to the base 10 of the other of the adjacent two mobile assemblies 1. One end of the support rod 202 is hinged with the transition platform 201, and the other end of the support rod 202 is movably connected to the arc-shaped guide groove 14. The adapter component 2 adopts the above structure, which facilitates the connection between the two adjacent mobile assemblies 1 and can ensure the overall stability when the mobile component 20 of one of the adjacent two mobile assemblies 1 drives the other to move.
In some optional embodiments, in the balance bearing device 100 provided in the embodiments of the present application, the adjusting component thereof may include a telescopic cylinder. One of the cylinder body and the cylinder rod of the telescopic cylinder is connected to the mobile component 20 and the other is connected to the base 10. The adjusting component 30 adopts the form of a telescopic cylinder, which can limit the limiting position of the mobile component 20 by limiting the stroke of the telescopic cylinder, avoiding the separation of the mobile component 20 from the corresponding base 10. Meanwhile, within the stroke range of the telescopic cylinder, when the mobile component 20 moves, the telescopic cylinder can move correspondingly without affecting the movement of the mobile component 20 under the action of gravity.
Optionally, the adjusting component 30 is connected to the base 10 and the mobile component 20 respectively in a hinged manner.
Please refer to
The balance bearing device 100 provided in the embodiments of the present application allows the mobile unit 22 to be connected to the bearing body 21 through the support frame 221, by the mobile unit 22 including the support frame 221, the traveling component 222, and the locking component 223. The support frame 221 can further provide connection and installation space for the locking component 223. The traveling component 222 disposed correspondingly can drive the entire mobile component 20 to move along the arc trajectory of the guide rail 11. The arrangement of the locking component 223 can lock the position of the traveling component 222 on the base 10, so as to lock the traveling component 222 when the balance bearing device 100 is in a non-operation state or in the case that the transport equipment 200 is inclined at a large angle and is about to tip over, avoiding the mobile component 20 from continuing to move along the guide rail 11 and saving energy. At the same time, the safety performance of the balance bearing device 100 is improved.
Optionally, the support frame 221 can adopt a frame structure, and a connection interface is provided on the support frame 221 for connecting with the bearing body 21.
Optionally, the support frame 221 can be a hollow frame structure, and the locking component 223 is at least partially located in the hollow cavity of the support frame 221. Through the above arrangement, the engagement between the locking component 223 and the support frame 221 is facilitated, while the overall structure of the mobile unit 22 is compact and occupies small space.
As shown in
The base 10 adopts the above structural form and the guide rail 11 is provided on the arc-shaped surface, which facilitates the formation of the arc-shaped guide rail 11. The traveling component 222 being supported at least partially on the top surface 12 can increase the contact area between the base 10 and the traveling component 222, share the pressure borne by the traveling component 222 through the arc-shaped surface, reduce friction during traveling, and ensure the smooth movement of the traveling component 222. At the same time, by allowing one of the traveling components 222 and the guide rail 11 to extend at least partially into the interior of the other and be movably connected to the other, it is possible to restrict the traveling components 222 to move always along the extension trajectory of the guide rail 11, thereby avoiding offset of the traveling components 222 relative to the guide rail 11.
Optionally, the bottom surface 13 of the base 10 can be a plane, facilitating connection with the mobile component 20 of the adjacent mobile assembly 1.
As an optional implementation, in the balance bearing device 100 provided in the embodiments of the present application, the guide rail 111 is an arc-shaped groove and the guide rail 11 is formed to be recessed from the top surface 12 towards the side close to the bottom surface 13. The traveling component 222 includes a traveling wheel 2221 and a clamping protrusion 2222 rotatably connected to the traveling wheel 2221. The traveling wheel 2221 is supported on the top surface 12 and rotatably connected to the locking component 223. The clamping protrusion 2222 is clamped inside the guide rail 11 and can move along the extension direction X of the guide rail 11.
Through the above arrangement, it is possible to restrict the movement of the traveling component 222 along the extension trajectory of the guide rail 11 by the coordination between the clamping protrusion 2222 and the guide rail 11, thereby avoiding offset of the traveling component 222 relative to the guide rail 11. The traveling wheel 2221 is in rolling engagement with the top surface 12, which facilitates the movement of the traveling component 222 and meanwhile sharing the pressure borne by the mobile unit 22 through the top surface 12.
Optionally, the clamping protrusion 2222 can be rotatably connected to the traveling wheel 2221, and alternatively, the clamping protrusion 2222 can rotate around the central axis of the traveling wheel 2221.
As shown in
As shown in
It can be understood that when one of the traveling components 222 and the guide rail 11 extends at least partially into the interior of the other and is movably connected to the other, the above structural form is not limited.
As shown in
Referring to
In the balance bearing device 100 provided in the embodiments of the present application, the locking component 223 adopting the above structural form can be connected to the support frame 221 through the installation body 2231, thereby providing support for the installation of the rotating body 2232 and the traveling component 222. Since the rotating body 2232 is rotatably connected to the installation body 2231 through the first rotating pair 2233 and the traveling component 222 is rotatably connected to the rotating body 2232 through the second rotating pair 2234, the traveling component 222 can rotate relative to the rotating body 2232 with the second rotating pair 2234 as the rotation center, thereby driving the mobile component 20 as a whole to move along the extension trajectory of the guide rail 11.
At the same time, the rotating body 2232 can drive the traveling component 222 as a whole to rotate relative to the installation body 2231 with the first rotating pair 2233 as the rotation center. As the rotation axis of the first rotating pair 2233 is parallel to the rotation axis of the second rotating pair 2234 and spaced apart from the rotation axis of the second rotating pair 2234, that is to say, the first rotating pair 2233 deviates from the rotation center of the traveling component 222, during the rotating of the rotating body 2232 with the first rotating pair 2233 as the rotation center, the traveling component 222 undergoes eccentric motion, which can increase the friction force between the traveling wheel 2221 and the supporting surface in contact with it, for example, the fiction between the traveling wheel 2221 and the top surface 12, so as to limit the traveling of the traveling component 222, thereby achieving the locking requirement.
Optionally, the first rotating pair 2233 can include a first rotating shaft and a first limiting cap located on at least one end of the first rotating shaft in the axial direction. The first rotating shaft can be fixedly connected to the rotating body 2232 and rotatably connected to the installation body 2231, and the first limiting cap is used to limit the separation of the first rotating shaft from the installation body 2231 in its own axial direction.
Optionally, the second rotating pair 2234 can include a second rotating shaft and a second limiting cap located on at least one end of the second rotating shaft in the axial direction. The second rotating shaft can be fixedly connected to one of the traveling wheel 2221 and the rotating body 2232 and rotatably connected to the other. The second limiting cap is used to limit the separation of the second rotating shaft from the traveling wheel 2221 or the rotating body 2232 in its own axial direction.
As an optional implementation, in the balance bearing device 100 provided in the embodiments of the present application, the rotating body 2232 includes a first rotating body 2232a and a second rotating body 2232b. The installation body 2231 is located between the first rotating body 2232a and the second rotating body 2232b. The first rotating pair 2233 is fixedly connected to the first rotating body 2232a and the second rotating body 2232b and is rotatably connected to the installation body 2231. The traveling component 222 is rotatably connected to the first rotating body 2232a.
The rotating body 2232 adopts the above structural form, so that when the rotating body 2232 rotates with the first rotating pair 2233 as the rotation center, the smoothness of rotation can be ensured and the connection with the traveling component 222 is facilitated. Optionally, the traveling wheel 2221 can be rotatably connected to the first rotating body 2232a through the second rotating pair 2234.
As an optional implementation, the locking component 223 provided in the embodiments of the present application further includes a driving assembly 2235, which drives the rotating body 2232 to rotate relative to the installation body 2231 with the first rotating pair 2233 as the rotation center. Through the above arrangement, the rotating body 2232 can be driven to rotate by the driving assembly 2235. When it is necessary to lock the traveling component 222, the driving assembly 2235 can drive the rotating body 2232 to rotate, thereby increasing the friction force between the traveling component 222 and the supporting surface in contact with it during the rotation of the rotating body 2232 with the first rotating pair 2233 as the rotation center, so as to limit the traveling of the traveling component 222, thereby achieving the locking requirement.
In some optional embodiments, the driving assembly 2235 includes an adjusting screw 2235a and a nut 2235b. One end of the adjusting screw 2235a is connected to the base 10 and the other end of the adjusting screw 2235a passes through the first rotating body 2232a. The nut 2235b is in threaded connection with the adjusting screw 2235a. The nut 2235b can move along the axial direction of the adjusting screw 2235a and squeeze the first rotating body 2232a to drive the rotating body 2232 as a whole to rotate relative to the installation body 2231 with the first rotating pair 2233 as the center.
In the balance bearing device 100 provided in the embodiments of the present application, the driving assembly 2235 includes the adjusting screw 2235a, so that one end of the adjusting screw 2235a is connected to the base 10 and the other end of the adjusting screw 2235a passes through the first rotating body 2232a. In the stacking direction Y, the nut 2235b is located on the side of the rotating body 2232 away from the base 10. When it is necessary to lock the traveling component 222, the nut 2235b can be screwed to move along the axial direction of the adjusting screw 2235a and squeeze the first rotating body 2232a so as to drive the rotating body 2232 as a whole to rotate relative to the installation body 2231 with the first rotating pair 2233 as the center, thereby achieving the locking of the traveling component 222.
When unlocking is necessary, the adjusting screw 2235a is separated from the base 10 and the nut 2235b is unlocked.
Optionally, the adjusting screw 2235a can extend along the stacking direction Y, which facilitates driving the first rotating body 2232a.
In some optional embodiments, in the balance bearing device 100 provided in the embodiments of the present application, the drive assembly 2235 may further include an electric driving component 2235c, one end of which is connected to the support frame 221 and the other end of which is engaged with the second rotating body 2232b to drive the rotating body 2232 as a whole to rotate relative to the installation body 2231 with the first rotating pair 2233 as the center.
When it is necessary to lock the traveling component 222, the electric driving component 2235c can further be controlled to drive the second rotating body 2232b to rotate. As the second rotating body 2232b is fixedly connected to the first rotating body 2232a through the first rotating pair 2233 to be a whole, and the first rotating pair 2233 is rotatably connected to the installation body 2231, hence when the second rotating body 2232b rotates, the first rotating pair 2233 drives the first rotating body 2232a to rotate with the first rotating pair 2233 as the rotation center, which can also achieve the locking of the traveling component 222.
Please refer to
The first rotating body 2232a adopts the above structural form, which can facilitate the engagement with the adjusting screw 2235a and the nut 2235b so as to ensure the rotation need.
As an optional implementation, in the axial direction of the adjusting screw 2235a, the extension size of the protruding part 22322 is smaller than that of the main body part 22321, and the surface of the protruding part 22322 that is engaged with the nut 2235b is a plane. Through the above arrangement, the interference between the adjusting screw 2235a, the nut 2235b and the base 10 can be effectively avoided when the first rotating body 2232a is driven to rotate with the first rotating pair 2233 as the rotation center, which facilitates the rotation of the first rotating body 2232a and can increase the rotation range of the first rotating body 2232a.
In some optional embodiments, the electric driving component 2235c includes a telescopic member which is connected to the second rotating body 2232b. The telescopic member extends or retracts to drive the second rotating member 2232b to rotate the first rotating body 2232a and the traveling component 222 with the first rotating pair 2233 as the center.
The electric driving component 2235c adopting the above structural form has simple structure, which facilitates the control and can ensure the driving requirement for the second rotating body 2232b.
As an optional implementation, the telescopic direction of the electric driving component 2235c can be perpendicular to the stacking direction Y, the second rotating body 2232b can be a strip like structure, and the driving end of the electric driving component 2235c can be connected on one side of the second rotating body 2232b and drive the second rotating body 2232b to rotate.
As shown in
As an optional implementation, in the balance bearing device 100 provided in the embodiments of the present application, multiple traveling components 222 are provided, and each traveling component 222 is correspondingly provided with a locking component 223. Through the above arrangement, the movement requirement of the mobile component 20 can be ensured, while the locking requirement of each traveling component 222 can be ensured, thereby improving safety performance.
Optionally, the number of traveling components 222 connected to the same support frame 221 can be two or more. Taking two traveling components 222 as examples, the two traveling components 222 can be spaced apart in the extension direction X of the guide rail 11, and each traveling component 222 can be correspondingly provided with one locking component 223. The installation body 2231 of each locking component 223 is connected to the support frame 221. The installation body 2231 of each locking component 223 connected to the same support frame 221 can be an integrated structure.
Please refer to
In some optional embodiments, in the balance bearing device 100 provided in the embodiments of the present application, the number of the mobile assemblies is two, and the extension trajectories of the guide rails 11 of the two mobile assemblies 1 are perpendicular to each other. Through the above arrangement, the balance bearing device 100 can drive the component 300 to be transported to adjust the balance by using gravity in two directions perpendicular to each other. The structure is simple and the need can be adjusted self-adaptively by using the gravity.
It can be understood that in the above embodiments, the telescopic cylinder adopted by the adjusting component 30 is only an optional implementation, but is not limited thereto.
Please refer to
The adjusting component 30, according to Hooke's theorem, has a restoring force when the displacement is maximum, which can alleviate and reduce the inclination of the angle and also meet the limiting effect.
Optionally, when the adjusting component 30 includes the elastic body, the number of the elastic bodies can be two, and the two elastic bodies are spaced apart and distributed on both sides of the mobile component 20 in the extension direction X of the guide rail of the mobile assembly 1.
Please refer to
Please refer to
That is to say, when the tilting condition is within the preset threshold range, the adjusting component 30 is in a following state. When the transport equipment 200 tilts, the mobile component 20 in the corresponding tilting direction can move along the extension trajectory of the corresponding guide rail 11 under the action of gravity to self-adaptively adjust the balance of the component 300 to be transported, thereby ensuring the safety of the component 300 to be transported.
It should be noted that the balance position mentioned above and below in the present application refers to the angle between the horizontal direction of the mobile component 20 for connection with the component 300 to be transported and the horizontal plane being 0°. That is to say, the surface for supporting the component 300 to be transported of the mobile component 20 in connection with the component 300 to be transported is in a horizontal state and the angle between the surface and the horizontal plane is 0°.
Optionally, the detector 3 can include either a displacement sensor or an inclination angle sensor, and the detector 3 can be provided on the transport equipment 200.
Optionally, the tilting condition includes the tilting angle A of the transport equipment 200 relative to the horizontal plane, and the preset threshold range includes −7°±0.5°≤A≤7°±0.5°. That is to say, the transport equipment 200 can tilt forward at an angle of less than or equal to 7°±0.5°, or tilt backward at an angle of less than or equal to 7°±0.5°.
Optionally, in some embodiments, the tilting condition can further include the displacement B of the mobile component 20 along the extension direction X of the corresponding guide rail 11. The preset threshold range further includes B1−B2≤B≤B1+B2, where B1 is the length size of the adjusting component 30 in the extension direction X of the guide rail 11 when the center of gravity of the mobile component 20 of the mobile assembly 1 for connection with the component 300 to be transported coincides with the center of gravity of the base 10 in the stacking direction Y, and B2 is the offset size of the center of gravity of the mobile component 20 of the mobile assembly 1 for connection with the component 300 to be transported relative to the center of gravity of the base 10 in the extension direction X of the guide rail 11 when the tilt angle of the transport equipment 200 reaches the preset threshold range.
As an optional implementation, in the balance bearing device 100 provided in the embodiments of the present application, the controller 4 are further configured to control the adjusting component 30 to provide a force opposite to the direction of movement of the mobile component 20 to the mobile component 20 when the tilting condition exceeds a preset threshold range.
That is to say, when the tilting condition includes the tilting angle A of the transport equipment 200 relative to the horizontal plane, and when A<−7°±0.5° or A>7°±0.5°, the adjusting component 30 is controlled to provide a force opposite to the direction of movement of the mobile component 20 to the mobile component 20 so as to avoid further movement of the mobile component 20 and the separation from the base 10.
When the tilting condition includes the displacement B of the mobile component 20 along the extension direction X of the corresponding guide rail 11, and when B>B1+B2 or B<B1−B2, the adjusting component 30 is controlled to provide a force opposite to the movement direction of the mobile component 20 to the mobile component 20 so as to avoid the mobile component 20 from continuously moving to separate from the base 10.
Of course, when the tilting condition exceeds the preset threshold range, the controller 4 can further control to lock the position of the mobile component 20 of each mobile assembly 1 relative to the base 10. When the driving assembly 2235 is included, the electric driving component 2235c of the driving assembly 2235 can be controlled to achieve locking by driving the traveling component 222 with the first rotating pair 2233 as the rotation center by the rotating body 2232.
Please refer to
S100, detecting the tilting condition of the transport equipment 200 where the balance bearing device 100 is located;
S200, when the tilting condition is within the preset threshold range, the respective mobile component 20 can be kept moving along the guide rail 11 under the action of gravity so that the mobile component 20 for connection with the component 300 to be transported is in the balance position.
Optionally, in step S100, the tilting condition may include the tilting angle A of the transport equipment 200 relative to the horizontal plane and/or the displacement B of the mobile component 20 along the extension direction X of the corresponding guide rail 11.
Optionally, in step S200, when the tilting condition is within the preset threshold range, the adjusting component 30 is in a following state. When the transport equipment 200 tilts, the mobile component 20 in the corresponding tilting direction can move along the extension trajectory of the corresponding guide rail 11 under the action of gravity to self-adaptively adjust the balance of the component 300 to be transported, thereby ensuring the safety of the component 300 to be transported.
As an optional implementation, the control method of the balance bearing device 100 provided in the embodiments of the present application further includes controlling the adjusting component 30 to provide a force opposite to the direction of movement of the mobile component 20 to the mobile component 20, and/or to lock the position of the mobile component 20 of each mobile assembly 1 relative to the base 10, when the tilting condition exceeds a preset threshold range.
When the tilting condition can include the inclination angle A of the transport equipment 200 relative to the horizontal plane and/or the displacement B of the mobile component 20 along the extension direction X of the corresponding guide rail 11. The threshold range of the inclination angle A and the threshold range of the displacement B are the same as the limitations in the balance bearing device 100 in the above embodiments, and will not be repeated herein.
As an optional implementation, the control method provided in the embodiments of the present application further includes detecting that the balance bearing device 100 is in a non-operation state and providing a locking signal.
The operator can control the driving assembly 2235 to drive the rotating body 2232 to rotate based on the locking signal, thereby achieving the locking of the position of the mobile component 20. In order for a better distinction, the manner of driving the first rotating body 2232a to rotate to achieve locking by engaging the adjusting screw 2235a with the nut 2235b is referred to as mechanical locking, and the manner of driving the second rotating body 2232b to rotate to achieve locking by the electric driving component 2235c is referred to as electromagnetic locking. And, the balance bearing device 100 can include two sets of mobile assemblies 1, the mobile assembly connected to the transport equipment 200 is referred to as the mobile component in the lower layer, and the adjusting component 30 is referred to as the adjusting component in the lower layer. The mobile assembly 1 arranged away from the transport equipment 200 and for connection with the component 300 to be transported is referred to as the mobile component in the upper layer, and the adjusting component 30 is referred to as the adjusting component in the upper layer.
In order to better understand the control method provided in the embodiments of the present application, specific examples will be provided below for explanation.
Please refer to
For example, when the inclination angle A is the front and back inclination angle, the controlled is performed by the adjusting component in the lower layer. When the inclination angle A is the left and right inclination angle, the controlled is performed by the adjusting component in the upper layer, and when the inclination angles are present both in the front and back direction and in the left and right direction, that is to say, when the front and back inclination angle and the left and right inclination angle are present, the control is performed simultaneously by the adjusting components in the lower layer and the upper layer.
When the inclination angle A of the mobile component 20 during the movement exceeds 7°±0.5°, the position of the mobile component 20 of each mobile assembly 1 relative to the base 10 is locked. Specifically, electromagnetic locking can be used to lock the traveling components 222. When the inclination angle A of the transport equipment 200 is less than or equal to 7°±0.5°, the electromagnetic lock is released and the adjusting is restarted.
When the inclination angle A of the transport equipment 200 detected by the inclination angle sensor is larger than 7°±0.5°, the shipping is stopped and the operation is stopped and the traveling component 222 is locked by electromagnetic locking.
Please refer to
The displacement sensor can be used to detect whether the displacement B of the mobile component 20 along the extension direction X of the corresponding guide rail 11 is within the preset threshold range. When B>B1+B2 or B<B1−B2, electromagnetic locking is used to lock the traveling component 222. When B1−B2≤B<B1+B2, the adjusting component 30 is in a following state.
Of course, it is also possible to detect whether the inclination angle A of the transport equipment 200 relative to the horizontal plane is within the preset threshold range by the inclination angle sensor. When A<−7°±0.5° or A>7°±0.5°, the electromagnetic locking is used to lock the traveling component 222. When −7°±0.5°≤A≤7°±0.5°, the adjusting component 30 is in a following state.
When the balance bearing device 100 is in a non-operation state, both mechanical locking and electromagnetic locking can be used to lock the traveling component 222, thus ensuring safety.
The control method of the balance bearing device 100 provided in the embodiments of the present application can meet the transportation requirements of the component 300 to be transported. When the tilting condition of the transport equipment 200 where the balance bearing device 100 is located is detected to be within the preset threshold range, the respective mobile component 20 can be kept moving along the guide rail 11 under the action of gravity so that the mobile component 20 for connection with the component 300 to be transported is in the balance position, thus achieving automatic balance adjustment under the action of gravity. When the tilting condition exceeds the preset threshold range, the locking of the traveling component 222 is used to ensure safety.
On the other hand, the present application further provides a transport equipment 200, and a balance bearing device 100 is arranged on the transport equipment 200. The transport equipment 200 can be a transport vehicle, a transport ship, etc.
Although the present application has been described with reference to preferred embodiments, various improvements can be made and components can be replaced with equivalents without departing from the scope of the present application. Especially, as long as there is no structural conflict, the various technical features mentioned in each embodiment can be combined in any way. This application is not limited to the specific embodiments disclosed in the text, but includes all technical solutions falling within the scope of the claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 202111276082.9 | Oct 2021 | CN | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/CN2022/080627 | 3/14/2022 | WO |
