MOVEMENT BUFFERING CONTROL SYSTEM AND METHOD FOR FORKLIFT TILT CYLINDER BASED ON ANGLE COMPENSATION

Abstract

The present application provides a movement buffering control system and method for forklift tilt cylinder based on angle compensation in the field of forklift control, which includes a tilt cylinder configured to control forward and backward tilting of a mast of a forklift and a lift cylinder configured to control the lifting of a fork, and further includes a controller, wherein a signal input terminal of the controller is connected to a first angle sensor to measure a tilt angle of the mast relative to a vertical plane, a second angle sensor to measure a tilt angle of a vehicle body relative to a level ground, and a pressure sensor, and wherein a signal output terminal of the controller is connected to a display, a forward-tilting proportional valve to control the oil for forward-tilting of the tilt cylinder.

Claims

1. A movement buffering control method for forklift tilt cylinder based on angle compensation, comprising the following steps: step 1: when a forklift is non-loaded on a level ground, a telescopic position of a tilt cylinder, corresponding to a vertical mast, being a neutral position of the cylinder, acquiring a limit forward-tilting angle B and a limit backward-tilting angle C of the mast tilted forward and backward from a vertical state; step 2: on the level ground, measuring and acquiring, by using a control variable method, a plurality of groups of mast deformation angles γ caused by load, and statistically calculating a corresponding relationship between load weights and γ; step 3: when the forklift operates, acquiring a current tilt angle α of the mast relative to a vertical plane, a current tilt angle β of a vehicle body relative to the level ground and a current load weight on a fork in real time when the vehicle body operates on the ground; step 4: calculating a tilt angle A of a current actual position of the mast with respect to the actual position of the mast currently corresponding to the neutral position of the cylinder in real time, A=α−β−γ; step 5: presetting a mast forward-tilting deceleration angle B1 and a mast backward-tilting deceleration angle C1, and judging whether the forklift is tilting forward or tilting backward: when the forklift is tilting forward, performing step 6; and when the forklift is tilting backward, performing step 7; step 6: comparing A, B and B1, when A=B1, a forward-tilting proportional valve in the forklift being controlled to reduce an amount of oil supplied to the tilt cylinder; and when A=B, the forward-tilting proportional valve cutting off an oil supply path to the tilt cylinder; and step 7: comparing A, C and C1, when A=C1, a backward-tilting proportional valve in the forklift being controlled to reduce an amount of oil supplied to the tilt cylinder; and when A=C, the backward-tilting proportional valve cutting off an oil supply path to the tilt cylinder.

2. The movement buffering control method for forklift tilt cylinder based on angle compensation according to claim 1, wherein the mast forward-tilting deceleration angle B1 is smaller than the limit forward-tilting angle B by 1° to 2°.

3. The movement buffering control method for forklift tilt cylinder based on angle compensation according to claim 1, wherein the mast backward-tilting deceleration angle C1 is smaller than the limit backward-tilting angle C by 1° to 2°.

4. A movement buffering control system for forklift tilt cylinder based on angle compensation, comprising a tilt cylinder configured to control forward and backward tilting of a mast of a forklift and a lift cylinder configured to control the lifting of a fork, and further comprising a controller, wherein a signal input terminal of the controller is connected to a first angle sensor to measure a tilt angle of the mast relative to a vertical plane, a second angle sensor to measure a tilt angle of a vehicle body relative to a level ground and a pressure sensor to measure a load weight on the fork, and wherein a signal output terminal of the controller is connected to a display to preset a mast forward-tilting deceleration angle and a mast backward-tilting deceleration angle, a forward-tilting proportional valve to control the oil for forward-tilting of the tilt cylinder, a backward-tilting proportional valve to control the oil for backward-tilting of the tilt cylinder and a lift solenoid valve to control the oil for lifting of the lift cylinder.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0021] FIG. 1 is a schematic structural diagram of a forklift in the prior art.

[0022] FIG. 2 is a schematic diagram of mast forward-tilting, mast in vertical and mast backward-tilting angles of a forklift.

[0023] FIG. 3 is a schematic diagrams of forward-tilting and backward-tilting angles when the ground is inclined and the forklift is non-loaded.

[0024] FIG. 4 is a schematic diagram of angles when the ground is level and the forklift is heavily loaded.

[0025] FIG. 5 is a schematic diagram of forward-tilting and backward-tilting angles when the ground is inclined and the forklift is heavily loaded.

[0026] In the drawings, 1: tilt cylinder; 2: mast; 3: fork; 4: vehicle body.

DESCRIPTION OF THE EMBODIMENTS

[0027] The technical solutions according to the embodiments of the present invention will be described clearly and completely below with reference to the accompanying drawings in the embodiments of the present invention. Apparently, the described embodiments are merely some of rather than all of the embodiments of the present invention. All other embodiments acquired by those of ordinary skill in the art without creative efforts based on the embodiments of the present invention shall fall within the protection scope of the present application.

[0028] As shown in FIG. 2, when the ground is level and the forklift is non-loaded, on the left is a limit forward-tilting angle B measured by an angle sensor when the mast tilts forward from a vertical state, which also corresponds to a maximum forward entending position of the tilt cylinder; in the middle is a telescopic position of the tilt cylinder when the mast is in the vertical state, which is called a neutral position of the cylinder; on the right is a limit backward-tilting angle C when the mast tilts backward from the vertical state, which also corresponds to a maximum backward extending position of the tilt cylinder. In order to make full and efficient use of the forklift, the tilt cylinder may be required to reach the maximum forward or backward extending position, regardless of whether the road surface is even or not.

[0029] When the mast or vehicle body tilts forward relative to the level ground, “+” represents a forward-tilting direction, and when the mast or vehicle body tilts backward, “−” represents a backward-tilting direction. In order to prevent the impact on the structural parts when the mast tilts to the limit, a buffering angle is set. When the buffering angle is reached, deceleration starts, and the movement speed decreases to 0 when reaching a limit forward-tilting angle or a limit backward-tilting angle.

[0030] Taking B=6° as an example, ideally, it is assumed that deceleration starts upon a forward tilt of 5° measured by the angle sensor, and the speed decreases to 0 when tilting forward to 6° measured by the angle sensor; taking C=−12° as an example, ideally, it is assumed that deceleration starts upon a backward tilt of −11° measured by the angle sensor, and the speed decreases to 0 when tilting backward to −12° measured by the angle sensor, so as to realize forward and backward tilt movement buffering.

[0031] As shown in FIG. 3, when the forklift is non-loaded and the ground is non-level, an angle β exists between the vehicle body and a level ground in a front-back direction, and an angle of the mast relative to a vertical plane (namely the position of the mast corresponding to the neutral position of the cylinder when the forklift is non-loaded on a level ground) measured by the angle sensor is α. A tilt angle of a current actual position of the mast relative to the actual position of the mast corresponding to the neutral position of the cylinder on the inclined ground is denoted as A.

[0032] Assuming that β=1°, a buffering angle is also set for buffering. In FIG. 3, on the left is a forward-tilted state of the forklift. In this case, the mast of the forklift starts to decelerate when moving to a position where the angle sensor measures α=5°, and the speed should decrease to 0 when α=6°. However, the vehicle body tilts by 1°, that is, the actual position of the mast corresponding to the neutral position of the cylinder is not in a vertical state, but tilts by 1°. Therefore, when the angle sensor measures α=5°, the angle of a current actual position of the mast relative to the actual position of the mast corresponding to the neutral position of the cylinder is A=α−β=4°, and deceleration starts when the mast has not reached the set buffering angle. When α=6°, A=α−β=5°, and the speed of the forklift decreases to 0 while the maximum forward extending position of the tilt cylinder has not been reached.

[0033] Similarly, on the right of FIG. 3 is a backward-tilted state of the forklift. When the angle sensor measures α=−11°, the forklift should start to decelerate, but the angle between a current actual position of the mast and the actual position of the mast corresponding to the neutral position of the cylinder is A=−(−α+β)=−12°. In this case, the tilt cylinder has actually reached the maximum backward extending position. When α=−12°, A=−13°, the movement of the forklift has already caused impact on the structural parts, without achieving a buffering effect.

[0034] As shown in FIG. 4, when the ground is level but the mast is deformed by a load, a deformation angle of the mast is assumed to be γ. The value of γ is actually a difference between angles of the mast relative to a vertical plane under heavy load and no load in the case of same ground flatness, tire pressure and telescopic length of the tilt cylinder.

[0035] In the case of forward-tilting movement, ideally, deceleration starts when α=5°, and the speed decreases to 0 when α=6°. Assuming that the deformation angle of the mast caused by heavy load is γ=0.2°, A=α−γ. When α is 5°, A=−−γ=4.8°. When α is 6°, A=α−γ=5.8°. As a result, the telescopic cylinder stops moving without reaching the maximum forward extending position. Although it has played a certain buffering effect, the range of forward-tilting movement is reduced, thus the buffering effect is not as good as expected, and the greater the deformation, the more notable the influence.

[0036] A movement buffering control system for forklift tilt cylinder according to this embodiment includes a tilt cylinder configured to control forward and backward tilting of a mast of a forklift and a lift cylinder configured to control the lifting of a fork, and further includes a controller, wherein a signal input terminal of the controller is connected to a first angle sensor to measure a tilt angle of the mast relative to a vertical plane, a second angle sensor to measure a tilt angle of the vehicle body relative to a level ground and a pressure sensor to measure a load weight on the fork. The controller further reads a signal from a handle of the forklift. A signal output terminal of the controller is connected to a display to preset a mast forward-tilting deceleration angle and a mast backward-tilting deceleration angle, a forward-tilting proportional valve to control the oil for forward-tilting of the tilt cylinder, a backward-tilting proportional valve to control the oil for backward-tilting of the tilt cylinder and a lift solenoid valve to control the oil for lifting of the lift cylinder.

[0037] This embodiment further provides a movement buffering control method for forklift tilt cylinder, including the following steps.

[0038] In step 1, when a forklift is non-loaded on a level ground, a telescopic position of a tilt cylinder, corresponding to a vertical mast, refers to a neutral position of the cylinder, a limit forward-tilting angle B (a maximum forward extending position of the tilt cylinder) and a limit backward-tilting angle C (a maximum backward extending position of the tilt cylinder) of the mast, to be tilted forward and backward from a vertical state, are acquired.

[0039] In step 2, on the level ground, a plurality of groups of mast deformation angles γ caused by load are measured and acquired by using a control variable method, and a corresponding relationship between load weights and γ is statistically calculated.

[0040] Specifically, in this step, γ may be obtained by a load test, in which the position of the mast is adjusted in the case of level ground and same tire pressure and no load, so that the tilt cylinder is located at the neutral position of the cylinder, the mast tilt angle α=0; and then the forklift is controlled to shovel and carry different tonnage of heavy objects. The pressure sensor is mounted on the lift cylinder or the lift solenoid valve. Load pressures are read by the pressure sensor. When the tilt cylinder is at the neutral position of the cylinder after loading, the measured value of the first angle sensor is γ. The pressure sensor collects loads of different tonnages, to obtain different pressure values and corresponding γ, and writes the pressure values generated by the loads and the deformation amounts of the mast into the controller.

[0041] In step 3, when the forklift operates, a current tilt angle α of the mast relative to a vertical plane, a current tilt angle β of the vehicle body relative to the level ground and a current load weight on the fork are acquired in real time when the vehicle body operates on the ground.

[0042] According to the current load weight on the fork and the corresponding relationship between load weights (pressure values) and γ measured in step 2, the currently relevant deformation angle γ of the mast is obtained.

[0043] In step 4, a tilt angle A of a current actual position of the mast with respect to the actual position of the mast currently corresponding to the neutral position of the cylinder is calculated in real time, that is, A=α−β−γ.

[0044] In step 5, a mast forward-tilting deceleration angle B1 and a mast backward-tilting deceleration angle C1 are preset through a display, and the controller judges, by reading angle values of the first angle sensor and the second angle sensor, whether the forklift is tilting forward or tilting backward: when the forklift is tilting forward, step 6 is performed; and when the forklift is tilting backward, step 7 is performed.

[0045] In step 6, A, B and B1 are compared, and when A=B1, a forward-tilting proportional valve in the forklift is controlled to reduce an amount of oil supplied to the tilt cylinder, and the forklift starts to decelerate; and when A=B, the tilt cylinder reaches a maximum forward extending position, and the forward-tilting proportional valve cuts off an oil supply path to the tilt cylinder, and the speed of the forklift decreases to 0.

[0046] In step 7, A, C and C1 are compared, and when A=C1, a backward-tilting proportional valve in the forklift is controlled to reduce an amount of oil supplied to the tilt cylinder, and the forklift starts to decelerate; and when A=C, the tilt cylinder reaches a maximum backward extending position, and the backward-tilting proportional valve cuts off an oil supply path to the tilt cylinder.

[0047] Specifically, when the road surface is uneven and the mast of the forklift is deformed due to heavy load, as shown in FIG. 5, in the left figure, when the forklift tilts forward, A=α−β−γ. Deceleration starts when A=B1, and deceleration stops when A=B. Thus a tilt forward up to a maximum forward extending position of the tilt cylinder can be achieved while realizing a buffering function, so that the forklift is fully utilized. In the right figure, in the case of backward tilting, the limit backward-tilting angle C is denoted as a negative value, A=−(−α+β−γ)=α−β−γ. Deceleration starts when A=C1, and the speed decreases to 0 when A=C. This enables the forklift to work upon a corresponding connection of the buffering angle with the actual deformation of the forklift and the ground slope/tilt angle, so as to really achieve a buffering effect.

[0048] Generally, the mast forward-tilting deceleration angle B1 is about 1° to 2° smaller than the limit forward-tilting angle B, and the mast backward-tilting deceleration angle C1 is about 1° to 2° smaller than the limit backward-tilting angle C. The mast forward-tilting deceleration angle B1 and the mast backward-tilting deceleration angle C1 may be set according to actual requirements.

[0049] The movement buffering control system and method for forklift tilt cylinder based on angle compensation according to the present invention may effectively solve the defect that the mast cannot tilt to a designed maximum angle dimension or move to a maximum position without timely buffering caused by the uneven ground and the deformation of the mast due to heavy load, has strong applicability, and can meet the requirements of various working conditions and working sites.

[0050] Although the specification is described according to the embodiments, an individual embodiment does not include only one independent technical solution. The description of the specification is merely for the sake of clarity, and those skilled in the art should take the specification as a whole, and individual technical solutions in the embodiments may also be appropriately combined to create other embodiments conceivable to those of ordinary skill in the art.

[0051] In the description of the present application, it should be noted that relational terms such as “first” and “second” may be used herein to distinguish one entity or operation from another entity or operation without necessarily requiring or implying any actual such relationship or order between such entities or operations. Moreover, the terms “include”, “comprise” or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or device that includes a series of elements, does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or device. Without further limitation, an element defined by the expression “including a/an . . . ” does not exclude the presence of additional element(s) in the process, method, article, or device that includes the element.

[0052] In the description of the present application, it should be further noted that, unless specifically stated and limited, the terms “arrange” and “connect” should be understood in a broad sense, such as, a fixed connection, a detachable connection, or an integral connection; a mechanical connection or an electrical connection; a direct connection, an indirect connection through an intermediate medium, or an internal connection of two elements. For those of ordinary skill in the art, the specific meanings of the above terms in the present disclosure can be understood on a case-by-case basis.

[0053] Therefore, the above are only preferred embodiments of the present invention and are not intended to limit the implementation scope of the present application. All equivalent changes made in accordance with the scope of the claims in the present application fall within the protection scope of the claims of the present application.