The present disclosure relates to controllers, and more particularly relate to a controller for a lifting platform and a lifting platform.
A conventional lifting platform generally leverages a controller to control actuators to bring a lifting column to lift and lower, where the controller and the actuators are connected via wires. To optimize wire length, an opening for the wires to access is usually arranged at a lateral side of the controller. When the wires are stressed, the wires are easy to fall off from the controller, causing disconnection between the controller and the actuators and rendering the controller unreliable in use.
Embodiments of the present disclosure provide a controller for a lifting platform and a lifting platform, which are reliable in use.
The present disclosure adopts the following technical solutions. A controller is adapted for a lifting platform, the lifting platform includes a lateral beam and actuators, and two actuators are provided and respectively disposed at two ends of the lateral beam. The controller includes a control box and a circuit board provided in the control box, the circuit board is connected to the actuators via wires, and a backside of the control box is connected to the lateral bean. Openings facilitating connection between the wire and the circuit board are arranged on the control box, and at least one of the openings is provided at a frontside of the control box.
Furthermore, the circuit board and the actuators are connected via the wire, and terminals for connecting with the wire are provided on the circuit board. The terminals are exposed via the openings.
Furthermore, the control box includes a base plate and a box body, and the control box is insert-fitted onto the lateral beam via the base plate.
Furthermore, a snap-fit buckle is provided on the lateral beam, and a slot fitted with the snap-fit buckle is provided on the base plate.
Furthermore, the slot is positioned on a lateral side of the base plate; or, the slot is disposed on a side of the base plate facing the lateral beam.
Furthermore, the snap-fit buckle and the lateral beam are integrally arranged; or, the snap-fit buckle and the lateral beam are separately arranged.
Furthermore, a slot is arranged on the lateral beam, and a snap-fit buckle fitted with the slot is arranged on the base plate.
Furthermore, the snap-fit buckle is arranged on a lateral side of the base plate; or, the snap-fit buckle is positioned on the side of the base plate facing the lateral beam.
The present disclosure further provides a lifting platform. The lifting platform includes a top, a lateral beam and a lifting column, which are supported underneath the top, an actuator for driving lifting and lowering of the lifting platform, and a controller disposed on the lateral beam. The controller refers to the controller in any of the above technical solutions.
In the present disclosure, the controller box is mounted on the lateral beam and arranged to face downward. The “backside of the controller” refers to the side of the control box facing the lateral beam, and the “frontside of the control box” refers to the side of the control box facing the ground.
With the above technical solutions, the present disclosure offers the following advantages.
1. In use, the actuators are disposed at the left and right sides of the control box. If the openings are arranged at the left and right sides of the control box, the wires between the actuators and the control box are easily pulled apart from the circuit board and thus fall off the control box, causing electrical disconnection between the actuators and the controller. In the present disclosure, at least one opening is disposed at the frontside of the control box, such that the actuators are not easily disengaged from the circuit board, rendering a more reliable connection between the control box and the actuators, further rendering the controller more reliable in use.
2. The wires are connected to the circuit board via terminals, wherein the terminals are exposed via the openings, such that the wires are insert-fitted with the terminals to realize connection with the circuit board, rendering wire connection simple and reliable.
3. The control box is insert-fitted onto the lateral beam via the base plate, rendering a simple and convenient connection between the controller and the lateral beam.
4. By providing a snap-fit buckle on the lateral beam and providing a slot on the base plate, or by providing a slot on the lateral beam and providing a snap-fit buckle on the base plate, fitting between the snap-fit buckle and the slot implements connection between the base plate and the lateral beam.
5. The present disclosure further provides a lifting platform, wherein the controller of the lifting platform refers to the controller described above, rendering a reliable connection between the controller and the actuators, further rendering the lifting platform reliable in use.
Hereinafter, the present disclosure will be described in further detail with reference to the accompanying drawings.
1. control box; 11. base plate; 12. box body; 121. opening; 2. snap-fit buckle; 21. limit notch; 3. slot; 31. stop block; 4. wire.
Hereinafter, the present disclosure will be described in further detail through preferred embodiments with reference to the accompanying drawings. It is understood that the terms such as “upper,” “lower,” “left,” “right,” “longitudinal,” “transverse,” “inner,” “outer,” “vertical,” “horizontal,” “top,” “bottom,” etc. only indicate the orientational or positional relationships based on the drawings, which are intended only for facilitating or simplifying description of the present disclosure, not for indicating or implying that the devices/elements must possess those specific orientations or must be configured and operated with those specific orientations; therefore, they should not be understood as limitations to the present disclosure.
As illustrated in
In this embodiment, the control box 1 comprises a base plate 11 and a box body 12. The control box is insert-fitted onto the lateral beam via the base plate, rendering mounting of the control box simpler and more convenient. A snap-fit buckle is provided on the lateral beam, and a slot 3 fitted with the snap-fit buckle is provided on the base plate 11. The slot is arranged at the side of the base plate facing the lateral beam, and the snap-fit buckle and the lateral beam are integrally arranged.
Specifically, the slot 3 refers to an inverted L-shaped slot, and the snap-fit buckle refers to an L-shaped snap-fit buckle. The snap-fit buckle and the slot are interference-fitted during assembly, such that once being assembled, the fitting between the slot and the snap-fit buckle is not easily disengaged, rendering a more reliable connection between the slot and the snap-fit buckle, and the control box does not easily fall off the lateral beam.
Two L-shaped snap-fit buckles are provided, and four inverted L-shaped slots are provided. The four slots are arranged in a pairwise symmetrical manner, such that the slots for fitting the snap-fit buckles are flexibly selected, and thus the position of the control box on the lateral beam is also flexibly selected.
The present disclosure further provides a lifting platform. The lifting platform includes a top, a lateral beam and a lifting column, which are supported underneath the top, actuators for driving lifting and lowering of the lifting platform, and a controller disposed on the lateral beam. The controller refers to the controller as described in any of the above technical solutions.
Because the connection between the controller and the actuators is more reliable and the connection between the control box and the lateral beam is simpler and more reliable, the lifting platform is also more reliable to use.
It is understood that the slots may also have an inverted “T” shape, and the snap-fit buckles have a “T” shape.
It is understood that it is alternative to arrange only one slot.
It is understood that it is alternative to arrange two slots.
As illustrated in
As illustrated in
In this embodiment, the slot 3 is a U-shaped slot, and the snap-fit buckle 2 is a U-shaped snap-fit. A stop block 31 is provided on a wall of the slot 3, and a limit notch 21 is provided on a sidewall of the snap-fit buckle 2. The snap-fit buckle 2 is inserted into the slot 3 such that the stop block 31 and the limit notch 21 are fitted to fix the position of the snap-fit buckle.
The snap-fit buckle is in threaded connection with the lateral beam. In use, the snap-fit buckle is removed from the slot and secured to the lateral beam via a bolt, and then the control box is secured to the lateral beam by fitting between the slot and the snap-fit buckle.
It is understood that the slot may also have a square shape, and the snap-fit buckle may also have a square shape.
As illustrated in
As illustrated in
The slot is provided on the lateral beam. The snap-fit buckle 2 fitted with the slot is provided on the base plate 11. Specifically, the snap-fit buckle is arranged on the side of the base plate facing the lateral beam. The snap-fit buckle is an L-shaped snap-fit buckle, wherein two snap-fit buckles are arranged to achieve a more secure fitting between the snap-fit buckles and the slot.
It is understood that the snap-fit buckle may also be arranged on a lateral side of the base plate.
Besides the preferred embodiments above, the present disclosure further has other embodiments. Those skilled in the art may make various alterations and transformations based on the present disclosure, which should all fall into the scope defined by the appended claims of the present disclosure without departing from the spirit of the present disclosure.
Filing Document | Filing Date | Country | Kind |
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PCT/CN2018/122212 | 12/20/2018 | WO |