Method and system for operating a tipper

Abstract

There is disclosed a method of operating a tipper comprising a tipper body pivotably moveable with respect to a frame with a hydraulic cylinder disposed therebetween which can be actuated by a hydraulic actuation system to pivot the tipper body. The method comprises receiving at least one lateral state parameter relating to at least one lateral state of the hydraulic cylinder; determining whether the lateral condition of the hydraulic cylinder is within acceptable limits based on the at least one lateral state parameter; and altering, or permitting the alteration of, at least one operational parameter of the hydraulic actuation system if it is determined that the lateral condition of the hydraulic cylinder is within acceptable limits.

Claims

1. A method of operating a tipper comprising a tipper body pivotably moveable with respect to a frame with a hydraulic cylinder disposed therebetween which can be actuated by a hydraulic actuation system to pivot the tipper body, the method comprising: receiving at least one lateral state parameter relating to at least one lateral state of the hydraulic cylinder; determining whether a lateral condition of the hydraulic cylinder is within acceptable limits based on the at least one lateral state parameter; and altering, or permitting the alteration of, at least one operational parameter of the hydraulic actuation system if it is determined that the lateral condition of the hydraulic cylinder is within acceptable limits.

2. A method according to claim 1, wherein a lateral inclination parameter is received which relates to a lateral inclination of the hydraulic cylinder, and wherein it is determined whether the lateral condition of the hydraulic cylinder is within acceptable limits based on at least the lateral inclination parameter.

3. A method according to claim 2, wherein the lateral inclination parameter is generated by an inclination sensor arranged to measure the lateral inclination of the hydraulic cylinder.

4. A method according to claim 3, wherein the inclination sensor is mounted to the hydraulic cylinder.

5. A method according to claim 2, wherein the lateral inclination parameter is generated by an inclination sensor arranged to measure the lateral inclination of the tipper body.

6. A method according to claim 5, wherein the inclination sensor is mounted to the tipper body.

7. A method according to claim 1, wherein a lateral bending parameter is received which relates to a lateral bending of the hydraulic cylinder, and wherein it is determined whether the lateral condition of the hydraulic cylinder is within acceptable limits based on at least the lateral bending parameter.

8. A method according to claim 1, wherein the pressure threshold of a pressure relief valve is increased, or it is permitted to increase the pressure threshold of a pressure relief valve, if it is determined that the lateral condition of the hydraulic cylinder is within acceptable limits.

9. A method according to claim 1, wherein the operational parameter comprises a pump speed of a pump of the hydraulic actuation system.

10. A method according to claim 9, wherein the pump speed is increased, or it is permitted to increase the pump speed, if it is determined that the lateral condition of the hydraulic cylinder is within acceptable limits.

11. A system for a tipper comprising a tipper body pivotably moveable with respect to a frame with a hydraulic cylinder disposed therebetween which can be actuated by a hydraulic actuation system to pivot the tipper body, the system comprising: a lateral condition determining module arranged to: receive at least one lateral state parameter relating to at least one lateral state of the hydraulic cylinder; determine whether the lateral condition of the hydraulic cylinder is within acceptable limits based on the at least one lateral state parameter; and a hydraulic actuation system control module arranged to alter, or permit alteration of, at least one operational parameter of the hydraulic actuation system if it is determined that the lateral condition of the hydraulic cylinder is within acceptable limits.

12. A system according to claim 11, wherein the lateral condition determining module is arranged to: receive a lateral inclination parameter relating to a lateral inclination of the hydraulic cylinder, and determine whether the lateral condition of the hydraulic cylinder is within acceptable limits based on at least the lateral inclination parameter.

13. A system according to claim 11, wherein the lateral condition determining module is arranged to: receive a lateral bending parameter relating to the lateral bending of the hydraulic cylinder, and determine whether the lateral condition of the hydraulic cylinder is within acceptable limits based on at least the lateral bending parameter.

14. A system according to claim 11, wherein the operational parameter comprises the pressure threshold of a pressure relief valve of the hydraulic actuation system.

15. A system according to claim 14, wherein the hydraulic actuation system control module is arranged to increase, or permit the increase of, a pressure threshold of a pressure relief valve, if it is determined that the lateral condition of the hydraulic cylinder is within acceptable limits.

16. A system according to claim 11, wherein the operational parameter comprises a pump speed of a pump of the hydraulic actuation system.

17. A system according to claim 16, wherein the hydraulic actuation system control module is arranged to increase, or permit increase of, the pump speed if it is determined that the lateral condition of the hydraulic cylinder is within acceptable limits.

18. A system according to claim 16, wherein the hydraulic actuation system control module is arranged to increase the pump speed from a default speed during only an intermediate phase of a tipping operation.

19. A tipper comprising: a tipper body pivotably moveable with respect to a frame; a hydraulic cylinder disposed between the frame and the tipper body and actuatable to pivot the tipper body; a hydraulic actuation system arranged to actuate the hydraulic cylinder; and a system in accordance with claim 11.

20. A method of operating a tipper comprising a tipper body pivotably moveable with respect to a frame with a hydraulic cylinder disposed therebetween which can be actuated by a hydraulic actuation system to pivot the tipper body, the method comprising: receiving at least one lateral state parameter relating to at least one lateral state of the hydraulic cylinder; determining whether a lateral condition of the hydraulic cylinder is within acceptable limits based on the at least one lateral state parameter; and altering, or permitting the alteration of, at least one operational parameter of the hydraulic actuation system if it is determined that the lateral condition of the hydraulic cylinder is within acceptable limits, wherein the operational parameter comprises a pressure threshold of a pressure relief valve of the hydraulic actuation system.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Embodiments of the invention will now be described, by way of example, with reference to the accompanying drawings, in which:

(2) FIG. 1 schematically shows a perspective view of a tipper truck;

(3) FIG. 2 schematically shows a side view of the tipper truck of FIG. 1 without the tractor;

(4) FIG. 3 schematically shows an end view of the tipper truck of FIG. 1 without the tractor and with the chassis inclined sideways;

(5) FIG. 4 schematically shows a first embodiment of a tipper control system for controlling the operation of a tipper;

(6) FIG. 5 schematically shows an end view of the tipper truck with the tipper body in a resting position;

(7) FIG. 6 schematically shows a graphical representation of pump speed as a function of tipper body position;

(8) FIG. 7 schematically shows a second embodiment of a tipper control system for controlling the operation of a tipper; and

(9) FIG. 8 schematically shows an alternative tipper truck.

DETAILED DESCRIPTION

(10) FIGS. 1 and 2 show a tipper truck 1, sometimes referred to as a dump truck, comprising a tractor 2 and a trailer 4. The trailer 4 has a trailer chassis or frame 6, and a tipper body 8 is pivotably mounted thereto. The tipper body 8 is pivotably mounted to the chassis 6 about a transverse axis 10 that is located at the rear of the chassis 6. The tipper body 8 is in the form of a cuboidal container having an open top. The rear panel (or door) 12 of the tipper body 8 is hinged at its upper edge and can be locked and unlocked such that it can be opened to allow the contents of the tipper body 8 to be emptied. A hydraulic cylinder 14 is provided that is pivotably attached at a lower end to the front of the chassis 6 and pivotably attached an upper end to the front of the tipper body 8. The hydraulic cylinder 14 can be extended (as in FIG. 1) to pivot the tipper body 8 about the axis 10 to a fully tipped position in which, with the rear panel 12 unlocked, any load within the tipper body 8 is emptied onto the ground. The tipper body 8 can be lowered back to the resting position under its own weight, thereby causing the cylinder 14 to retract.

(11) The tipper truck 1 further comprises a hydraulic actuation system 20 for actuating the hydraulic cylinder 14. The hydraulic actuation system 20 comprises an oil tank 22, a pump 24 and a valve assembly 26 that are connected with fluid lines to form a fluid circuit. A pilot system (not shown) is also provided for switching the valve assembly 26 between various configurations. The valve assembly 26 is provided with a port that is hydraulically connected to the hydraulic cylinder 14 with a fluid line 28. The valve assembly 26 can be switched between a number of configurations in order to operate the hydraulic cylinder 14. In a bypass configuration of the valve assembly 26, with the pump 24 running, hydraulic fluid is circulated by the pump 24 from the tank 22, through the valve assembly 26 back to the tank 22. In order to extend the hydraulic cylinder 14 to pivot the tipper body 8 to a fully tipped position (as in FIGS. 1 and 2), the valve assembly 26 is switched to a raising configuration in which the pump 24 pumps hydraulic fluid from the tank 22 into the hydraulic cylinder 14, thus causing it to extend. The speed of the pump 26 is set at a default baseline speed. The pump speed relates to the flow rate of the hydraulic fluid and thus the speed at which the hydraulic cylinder 14 is extended. When the hydraulic cylinder 14 has been sufficiently extended (either fully extended or extended by the desired amount), the valve assembly 26 is returned to a bypass configuration in which, with the pump 24 running, hydraulic fluid is circulated from the tank 22 through the valve assembly 26 back to the tank 22. In the bypass configuration of the valve assembly 26 the fluid line 28 is closed and therefore the cylinder 14 remains in the extended configuration. In this embodiment, the hydraulic actuation system 20 is provided with an automatic knock-off which automatically switches the valve assembly 26 to the bypass configuration when the hydraulic cylinder has been fully extended. The automatic knock-off is in the form of a switch which the body of the hydraulic cylinder 14 triggers when it reaches the fully extended position. In order to lower the hydraulic cylinder 14, the pump 24 is shut off and the valve assembly 26 is switched to a lowering configuration. In this configuration, the fluid line 28 is opened and the cylinder 14 retracts under the weight of the tipper body 8 with the hydraulic fluid being returned to the tank 22.

(12) The valve assembly 26 is also provided with a pressure relief bypass valve 27 set at a threshold default (baseline) pressure. If the pressure of the hydraulic fluid in the valve assembly 26 reaches the threshold pressure (which may be due to an excessively heavy load in the tipper body 8) the hydraulic fluid is diverted to the tank 22, rather than being pumped into the hydraulic cylinder 14. This is a safety feature provided to prevent excessively heavy loads from being lifted.

(13) Referring to FIG. 3, if the ground is uneven, the chassis 6 may be inclined sideways at an angle (i.e. one side of the chassis 6 may be higher than the other side of the chassis 6). If there is a sideways inclination of the chassis 6 then the longitudinal axis A of the hydraulic cylinder 14 will be also be laterally inclined by an angle (i.e. the longitudinal axis A of the hydraulic cylinder will have a transverse component). In this embodiment the inclination angle is defined with reference to vertical. However, the inclination angle could be defined with reference to horizontal (i.e. 90 equates to the cylinder 14 being vertical). With the chassis 6 inclined sideways, the centre of gravity of the load will move laterally as the hydraulic cylinder 14 is extended. This may cause the tipper truck 1 to topple over sideways, or it may cause the hydraulic cylinder 14 to bend and potentially buckle, which in turn may cause the tipper truck 1 to topple over sideways. Further, if the load within the tipper body 8 is not located laterally centrally then the hydraulic cylinder 14 may bend as it is extended, which may cause the cylinder 14 to buckle and the tipper truck 1 to topple.

(14) As will be described in detail below, the tipper truck 1 is provided with a tipper control system 40 which can determine whether the lateral condition of the hydraulic cylinder 14 is within acceptable limits and, if so, optimise the operation of the tipper 1.

(15) FIG. 4 shows the tipper control system 40 for determining whether the lateral condition of the hydraulic cylinder is within acceptable limits based on two lateral states: lateral inclination and lateral bending. In this embodiment the lateral condition of the cylinder is a combination of lateral inclination and lateral bending of the cylinder 14. However, it should be appreciated that in other embodiments the lateral condition may include other factors, or may relate to only one condition (e.g. lateral inclination). The tipper control system 40 comprises an inclination (or tilt) sensor 42 for measuring the inclination (i.e. the tilt angle) of the hydraulic cylinder 14 in a plane parallel to the lower pivot axis 30. The lower pivot axis 30 of the cylinder 14 is defined by the axis of the eye 32 by which the cylinder 14 is pivotably mounted to the chassis 6. Similarly, the upper pivot axis 34 (which is parallel to the lower axis 30) is defined by the axis of the eye 36 by which the cylinder 14 is pivotably mounted to the tipper body 8. The inclination sensor 42 is mounted to the outer surface of the hydraulic cylinder 14 and is positioned such that it can measure the lateral (i.e. sideways) inclination of the hydraulic cylinder 14 in a vertical plane parallel to the pivot axis 30. The inclination sensor 42 is arranged to generate an electronic signal which is representative of the inclination angle . The tipper control system 40 also comprises first and second bending sensors 44, 46 in the form of strain gauges. The strain gauges 44, 46 are bonded to the hydraulic cylinder 14 and are located on opposing sides. The strain gauges 44, 46 are arranged to generate electronic signals which are representative of the lateral bending force experienced by the hydraulic cylinder 14 in a plane parallel to both the pivot axis 30 and the longitudinal axis of the cylinder 14. It should be appreciated that other bending sensors located in other suitable positions could be used. For example, one or more strain gauges could be bounded to the inside of a trunnion pin that passes through the eye 32 to provide a signal representative of bending. In another arrangement strain gauges could be bonded to the chassis bracket (not shown) which the trunnion pin passes through to provide a signal representative of bending.

(16) The tipper control system 40 further comprises a lateral condition determining module 50, a hydraulic actuation system control module 52 and a display 54. The inclination sensor 42 and the first and second bending sensors 44, 46 are connected to the lateral condition determining module 50 by appropriate cabling such that the lateral condition determining module 50 can obtain the signals generated by the sensors 42, 44, 46. It should be appreciated that in other embodiments the sensors 42, 44, 46 could be wirelessly connected to the lateral condition determining module 50. The lateral condition determining module 50 is configured to monitor the signals received from the inclination sensor 42 and the two bending sensors 44, 46, and based on these signals, determine whether the lateral condition of the hydraulic cylinder 14 is within acceptable limits (i.e. if both the angle of lateral inclination and the lateral are suitably small). The hydraulic actuation system control module 52 is connected to the speed controller of the pump 24 and to the pressure relief valve 27 of the valve assembly 26. The hydraulic actuation system control module 52 can automatically increase the pump speed and/or increase the pressure threshold of the pressure relief valve 27 if it is determined that the lateral condition of the hydraulic cylinder 14 is within acceptable limits. The hydraulic actuation system control module 52 may be connected either wired or wirelessly to the pump 24 and/or the valve assembly 26. In other embodiments, instead of the pump speed and threshold pressure being automatically adjusted, a prompt could be displayed to the operator to allow the operator to manually change the speed and/or pressure. The display 54 is connected to the lateral condition determining module 50 and is configured to display an alert if the lateral condition determining module 50 determines that the lateral condition of the hydraulic cylinder 14 is with acceptable limits. The display 54 is an LCD screen configured to display a visual alert, and a sounder is also provided to generate an audible alert. In this embodiment the display 54 is installed in the dashboard of the tractor 2 such that it is easily visible by an operator. However, in other embodiments it could be located externally, or it could be in the form of a wireless hand-held device (e.g. a smartphone or a tablet). If the display 54 is provided by a portable wireless device, such as a smartphone or tablet, it could also incorporate the lateral condition determining module 50 and the hydraulic actuation system control module 52 and could communicate wirelessly with the sensors 42, 44, 46. It should be appreciated that other displays, such as an LED could be used to provide a warning.

(17) The operation of the tipper 1 will now be described with reference to FIG. 5.

(18) Before commencing a tipping operation, the tipper body 8 containing a load 16 (such as sand) is in a resting position (FIG. 5). In the resting position of the tipper body 8 it rests on the chassis 6 of the trailer 4 such that the load is transferred directly to the chassis 6. The tipper control system 40 continuously monitors the signals received from the inclination sensor 42 and the bending sensors 44, 46 to determine if the lateral condition of the hydraulic cylinder 14 is within acceptable limits. Specifically, the lateral condition determining module 50 continuously monitors the value of the inclination signal generated by the inclination sensor 42 (lateral inclination parameter) and the values of the bending signals generated by the first and second bending sensors 44, 46 (lateral bending parameter). The value of the inclination signal relates to the lateral (sideways) inclination angle of the hydraulic cylinder 14, whilst the value of the bending signals can be converted to a lateral bending moment experienced by the hydraulic cylinder 14. These values could be displayed on the display 56, but this is not essential. The lateral condition determining module 50 analyses the inclination signal and the bending signals and utilises an algorithm to determine whether the lateral condition of the hydraulic cylinder 14 is within acceptable limits. In this embodiment, this is done by the lateral condition determining module 50 determining (a) whether the lateral inclination angle of the cylinder 14 is below a threshold (i.e. is the angle sufficiently small), and (b) whether the lateral bending of the cylinder is below a threshold (i.e. is the bending sufficiently low). If neither of these thresholds are met (i.e. if both the angle and the bending are sufficiently low), then the lateral condition determining module 50 determines that the lateral condition of the hydraulic cylinder 14 is acceptable (i.e. it is within acceptable limits). For example, as can be seen from FIG. 5, the inclination angle is negligible and thus the bending will also be negligible. In response to this determination, the lateral condition determining module 50 communicates to the hydraulic actuation system control module 52 which optimises the tipping operation when commenced.

(19) Specifically, in this embodiment since the lateral condition of the hydraulic cylinder 14 is within acceptable limits (i.e. it is in an ideal lateral condition) the threshold default pressure of the pressure relief valve 27 is increased by 20%. This means that the tipper 1 is capable of tipping a heavier than normal load, but only because the lateral condition of the cylinder 14 is within acceptable limits. Further, referring to FIG. 6, the speed of the pump 26 is programmed so that it is increased only for an intermediate phase of the tipping operation. In this embodiment the pump speed is set so that the speed is increased by 25% between 25% of fully tipped to 75% of fully tipped. This means that when a tipping operation is commenced (for example when an operator uses a control level (not shown) to extend the cylinder 14), the cylinder 14 initially extends slowly (0-25%), then the speed of extension increases (25%-75%), and then the speed of extension reduces again (75%-100%). This results in a quicker tipping operation, but prevents the cylinder 14 being damaged by the cylinder being extended too quickly with a low load (i.e. in the final phase of extension).

(20) The tipper control system 40 continuously monitors the signals generated by the sensors 42, 44, 46 and the lateral condition determining module 50 continuously assesses whether the lateral condition of the hydraulic cylinder 14 is within acceptable limits. Specifically, even after a tipping operation has been commenced (i.e. when the tipper body 8 is pivoted away from the resting position), the lateral condition determining module 50 checks to ascertain whether the lateral inclination angle is low enough and if the lateral bending is low. If it is ascertained that either of these parameters are outside acceptable limits, the hydraulic actuation system control module 52 may control the hydraulic actuation system 20 to reduce the threshold pressure of the pressure relief valve 27, or it may reduce the pump speed. In other embodiments it may in fact automatically halt (stop) the tipping operation and the hydraulic cylinder 14 may be retracted to lower the tipper body 8 to the resting position.

(21) FIG. 7 shows a second embodiment of a tipper control system 140 which is similar to the first embodiment. However, in the second embodiment there are no sensors mounted to the hydraulic cylinder 14. Instead, an inclination sensor 48 is provided which is mounted to the tipper body 8. The inclination sensor 48 is arranged such that it can measure the lateral inclination (i.e. side-to-side inclination) of the tipper body 8. The output of the inclination sensor 48 depends on both the lateral inclination and the lateral bending of the hydraulic cylinder 14. Therefore, the output of the inclination sensor 48 generates a signal relating to the lateral state of the hydraulic cylinder. As in the first embodiment, the lateral condition determining module 150 receives the output of the inclination sensor 48 and determines whether the lateral condition of the hydraulic cylinder 14 (and thus the tipper body 8 itself) is within acceptable limits. If it is determined that the lateral condition of the cylinder 14 is within acceptable limits then an operational parameter of the hydraulic actuation system 20 may be automatically altered, or it may be permitted to manually alter such an operational parameter. The operational parameters may be any suitable parameter such as pump speed or the threshold pressure of a pressure relief valve. Providing an inclination sensor 48 on the tipper body 8 may be advantageous in that a single sensor can be used to provide an indication of cylinder inclination and bending.

(22) It has been described that the lateral condition determining module 50 monitors both the lateral inclination and the lateral bending of the hydraulic cylinder 14. However, it should be appreciated that the module 50 may monitor only one of these conditions (e.g. only inclination or only bending). In other embodiments, the module 50 may monitor other conditions as well.

(23) In the embodiment described above the lateral condition determining module 50 determines that the lateral condition of the hydraulic cylinder 14 is within acceptable limits if the lateral inclination is below a threshold and the lateral bending is below a threshold. However, other ways of determining that the lateral condition of the hydraulic cylinder is within acceptable limits could be used.

(24) It has been described that the inclination sensor 42 generates a signal representative of the lateral inclination of the hydraulic cylinder 14 by using an inclination sensor mounted to the cylinder 14. However, the lateral inclination of the hydraulic cylinder 14 could be monitored by using an inclination sensor mounted to the chassis 6 of the tipper measuring the sideways inclination . It should be appreciated that any suitable sensors positioned in any appropriate location could be used to generate a signal indicative of or related to the lateral inclination of the hydraulic cylinder 14. Further, although it has been described that there are two bending sensors 44, 46, it should be appreciated that any suitable number of sensors could be used. For example, for a telescoping cylinder, one or more bending sensors could be attached to each stage of the cylinder.

(25) In the above described embodiment operational parameters (e.g. pump speed and threshold pressure) are automatically altered if the lateral condition of the hydraulic cylinder is acceptable. However, in other embodiments the display could generate a prompt allowing the operator to alter operational parameters if it is determined that the lateral condition of the cylinder is within acceptable limits.

(26) It should be appreciated that other operation parameters of the hydraulic control system could be altered in addition to or instead of pump speed and threshold pressure of the pressure relief valve. Further, the operational parameters could be altered in any suitable way. For example, a step-change in pump speed could be provided, or the speed could be gradually increased over a period of time.

(27) In another embodiment a pressure sensor is provided to generate a pressure parameter relating to the pressure of the hydraulic fluid within the hydraulic cylinder 14. This could be in the form of a pressure sensor mounted to a port of the hydraulic cylinder 14. In such an embodiment, the lateral condition determining module 50 would also monitor the pressure parameter relating to hydraulic pressure within the hydraulic cylinder 14 (which relates to the load within the tipper body) and would determine whether the lateral condition of the cylinder is within acceptable limits based on the lateral state parameters (e.g. lateral inclination parameter and/or lateral bending parameter), and the pressure parameter.

(28) It should be appreciated that the system could be used with any suitable type of tipper truck in which a tipper body 8 can be pivoted or moved by a hydraulic cylinder. For example, as shown in FIG. 8, the tipper truck 1 may comprises a tractor 2 having a frame 6 with a hydraulic cylinder 14 connected between the frame 6 and the tipper body 8. The tipper truck 14 further comprises a drawbar 11 that is pivotably connected at a first end to the frame 6 at a first pivot axis 10 and at a second end to the tipper body 8 at a second pivot axis 11. In order to pivot the tipper body 8 from a resting position (not shown) to the fully tipped position (FIG. 8), the hydraulic cylinder 14 is extended which causes the tipper body 8 to pivot clockwise (in FIG. 8) with respect to the frame 6 about the pivot axis 10, and with respect to the drawbar 9 about the pivot axis 11. It should also be appreciated that in order to measure the angular position (i.e. tip angle) of the tipper body 8 the inclination angle of the drawbar 9 could be measured since there is a fixed relationship between this angle and the tip angle (and the inclination angle of the hydraulic cylinder 14).

(29) The tipper control system 40 may be one of many intelligent systems that the tipper truck 1 is provided with and could therefore be combined with any suitable system for providing information regarding the tipper vehicle and/or the load carried by the tipper body. If multiple intelligent systems are provided, they may share the same display or processors, for example.

(30) Some aspects of the above-described apparatus, system and methods, may be embodied as machine readable instructions such as processor control code, for example on a non-volatile carrier medium such as a disk, CD- or DVD-ROM, programmed memory such as read only memory (Firmware), or on a data carrier such as an optical or electrical signal carrier. For some applications, embodiments of the invention will be implemented on a DSP (Digital Signal Processor), ASIC (Application Specific Integrated Circuit) or FPGA (Field Programmable Gate Array). Thus the code may comprise conventional program code or microcode or, for example code for setting up or controlling an ASIC or FPGA. The code may also comprise code for dynamically configuring re-configurable apparatus such as re-programmable logic gate arrays. Similarly the code may comprise code for a hardware description language such as Verilog or VHDL (Very high speed integrated circuit Hardware Description Language). The code may be distributed between a plurality of coupled components in communication with one another. Where appropriate, embodiments may also be implemented using code running on a field-(re)programmable analogue array or similar device in order to configure analogue hardware.

(31) For the avoidance of doubt, the present application extends to the subject-matter described in the following numbered paragraphs (referred to as Para or Paras):

(32) A method of operating a tipper comprising a tipper body pivotably moveable with respect to a frame with a hydraulic cylinder disposed therebetween which can be actuated by a hydraulic actuation system to pivot the tipper body, the method comprising: receiving at least one lateral state parameter relating to at least one lateral state of the hydraulic cylinder; determining whether the lateral condition of the hydraulic cylinder is within acceptable limits based on the at least one lateral state parameter; and altering, or permitting the alteration of, at least one operational parameter of the hydraulic actuation system if it is determined that the lateral condition of the hydraulic cylinder is within acceptable limits.

(33) A method, wherein a lateral inclination parameter is received which relates to the lateral inclination of the hydraulic cylinder, and wherein it is determined whether the lateral condition of the hydraulic cylinder is within acceptable limits based on at least the lateral inclination parameter.

(34) A method, wherein the lateral inclination parameter is generated by an inclination sensor arranged to measure the lateral inclination of the hydraulic cylinder.

(35) A method, wherein the inclination sensor is mounted to the hydraulic cylinder.

(36) A method, wherein the lateral inclination parameter is generated by an inclination sensor arranged to measure the lateral inclination of the tipper body.

(37) A method, wherein the inclination sensor is mounted to the tipper body.

(38) A method, wherein a lateral bending parameter is received which relates to the lateral bending of the hydraulic cylinder, and wherein it is determined whether the lateral condition of the hydraulic cylinder is within acceptable limits based on at least the lateral bending parameter.

(39) A method, wherein the lateral bending parameter is generated by at least one bending sensor arranged to measure the lateral bending of the hydraulic cylinder.

(40) A method, wherein the bending sensor is mounted to the hydraulic cylinder.

(41) A method, wherein first and second bending sensors are mounted either side of the hydraulic cylinder.

(42) A method, wherein the or each bending sensor comprises a strain gauge.

(43) A method, further comprising receiving a pressure parameter relating to the hydraulic pressure within the hydraulic cylinder, wherein it is determined whether the lateral condition of the hydraulic cylinder is within acceptable limits based on the at least one lateral state parameter and the pressure parameter.

(44) A method, wherein the pressure parameter is generated by a pressure sensor which measures the hydraulic pressure within the hydraulic cylinder.

(45) A method, wherein the pressure sensor is mounted to the hydraulic cylinder.

(46) A method, wherein determining whether the lateral condition of the hydraulic cylinder is within acceptable limits comprises comparing at least one lateral state parameter with reference data.

(47) A method, wherein determining whether the lateral condition of the hydraulic cylinder is within acceptable limits comprises utilising an algorithm which considers at least two different types of lateral state parameter.

(48) A method, further comprising generating an alert if it is determined that the lateral condition of the hydraulic cylinder is within acceptable limits.

(49) A method, wherein the alert comprises a visual and/or an audible alert.

(50) A method, wherein the operational parameter comprises the pressure threshold of a pressure relief valve of the hydraulic actuation system.

(51) A method, wherein the pressure threshold of a pressure relief valve is increased, or it is permitted to increase the pressure threshold of a pressure relief valve, if it is determined that the lateral condition of the hydraulic cylinder is within acceptable limits.

(52) A method, wherein the operational parameter comprises the pump speed of a pump of the hydraulic actuation system.

(53) A method, wherein the pump speed is increased, or it is permitted to increase the pump speed, if it is determined that the lateral condition of the hydraulic cylinder is within acceptable limits.

(54) A method, wherein the at least one operational parameter is automatically increased if it is determined that the lateral condition of the hydraulic cylinder is within acceptable limits.

(55) A method, further comprising performing a tipping operation in which the tipper body is pivoted from a resting position towards a tipping position.

(56) A method, wherein it is determined whether the lateral condition of the hydraulic cylinder is within acceptable limits based on the at least one lateral state parameter prior to commencement of the tipping operation.

(57) A method, wherein it is determined whether the lateral condition of the hydraulic cylinder is within acceptable limits based on the at least one lateral state parameter during the tipping operation.

(58) A method, wherein the pump speed is increased from a default speed during only an intermediate phase of a tipping operation.

(59) A system for a tipper comprising a tipper body pivotably moveable with respect to a frame with a hydraulic cylinder disposed therebetween which can be actuated by a hydraulic actuation system to pivot the tipper body, the system comprising: a lateral condition determining module arranged to: receive at least one lateral state parameter relating to at least one lateral state of the hydraulic cylinder; determine whether the lateral condition of the hydraulic cylinder is within acceptable limits based on the at least one lateral state parameter; and a hydraulic actuation system control module arranged to alter, or permit the alteration of, at least one operational parameter of the hydraulic actuation system if it is determined that the lateral condition of the hydraulic cylinder is within acceptable limits.

(60) A system, wherein the lateral condition determining module is arranged to: receive a lateral inclination parameter relating to the lateral inclination of the hydraulic cylinder, and determine whether the lateral condition of the hydraulic cylinder is within acceptable limits based on at least the lateral inclination parameter.

(61) A system, further comprising an inclination sensor arranged to measure the lateral inclination of the hydraulic cylinder and generate the lateral inclination parameter.

(62) A system, further comprising an inclination sensor arranged to measure the lateral inclination of the tipper body and generate the lateral inclination parameter.

(63) A system, wherein the lateral condition determining module is arranged to: receive a lateral bending parameter relating to the lateral bending of the hydraulic cylinder, and determine whether the lateral condition of the hydraulic cylinder is within acceptable limits based on at least the lateral bending parameter.

(64) A system, further comprising at least one bending sensor arranged to measure the lateral bending of the hydraulic cylinder and generate the lateral bending parameter.

(65) A system, further comprising first and second bending sensors arranged to be mounted either side of the hydraulic cylinder.

(66) A system, wherein the or each bending sensor comprises a strain gauge.

(67) A system, wherein the lateral condition determining module is arranged to: receive a pressure parameter relating to the hydraulic pressure within the hydraulic cylinder; and determine whether the lateral condition of the hydraulic cylinder is within acceptable limits based on the at least one lateral state parameter and the pressure parameter.

(68) A system, further comprising a pressure sensor which is arranged to measure the hydraulic pressure within the hydraulic cylinder and generate the pressure parameter.

(69) A system, further comprising a storage module storing reference data, and wherein the lateral condition determining module is arranged to determine whether the lateral condition of the hydraulic cylinder is within acceptable limits by comparing at least one lateral state parameter with reference data stored in the storage module.

(70) A system, wherein the lateral condition determining module is arranged to determine whether the lateral condition of the hydraulic cylinder is within acceptable limits by utilising an algorithm which considers at least two different types of lateral state parameter.

(71) A system, wherein the operational parameter comprises the pressure threshold of a pressure relief valve of the hydraulic actuation system.

(72) A system, wherein the hydraulic actuation control system is arranged to increase, or permit the increase of, the pressure threshold of a pressure relief valve, if it is determined that the lateral condition of the hydraulic cylinder is within acceptable limits.

(73) A system, wherein the operational parameter comprises the pump speed of a pump of the hydraulic actuation system.

(74) A system, wherein the hydraulic actuation control system is arranged to increase, or permit the increase of, the pump speed if it is determined that the lateral condition of the hydraulic cylinder is within acceptable limits.

(75) A system, wherein the hydraulic actuation system control module is arranged to automatically increase the at least one operational parameter if it is determined that the lateral condition of the hydraulic cylinder is within acceptable limits.

(76) A system, wherein the lateral condition determining module is arranged to determine whether the lateral condition of the hydraulic cylinder is within acceptable limits based on the at least one lateral state parameter prior to commencement of a tipping operation.

(77) A system, wherein the lateral condition determining module is arranged to determine whether the lateral condition of the hydraulic cylinder is within acceptable limits based on the at least one lateral state parameter during a tipping operation.

(78) A system, wherein the hydraulic actuation system control module is arranged to increase the pump speed from a default speed during only an intermediate phase of a tipping operation.

(79) A system, further comprising an operator input device for performing a tipping operation in which the tipper body is pivoted from a resting position towards a tipped position.

(80) A tipper comprising: a tipper body pivotably moveable with respect to a frame; a hydraulic cylinder disposed between the frame and the tipper body and actuatable to pivot the tipper body; a hydraulic actuation system arranged to actuate the hydraulic cylinder; and a system in accordance.

(81) A tipper, wherein the inclination sensor is mounted to the hydraulic cylinder.

(82) A tipper, wherein the inclination sensor is mounted to the tipper body.

(83) A tipper, wherein the bending sensor is mounted to the hydraulic cylinder.

(84) A tipper, wherein the first and second bending sensors are mounted either side of the hydraulic cylinder.

(85) A tipper, wherein the pressure sensor is mounted to the hydraulic cylinder.

(86) A tipper, wherein the hydraulic actuation system comprises a hydraulic fluid tank, a pump and a valve assembly having a pressure relief valve.

(87) A hydraulic cylinder assembly comprising: a hydraulic cylinder having at least one pivot axis perpendicular to the longitudinal axis of the cylinder; and at least one inclination sensor coupled to the hydraulic cylinder such that it is capable of generating a lateral inclination parameter relating to the inclination of the cylinder in a plane parallel to the pivot axis; and/or at least one bending sensor coupled to the hydraulic cylinder such that it is capable of generating a lateral bending parameter relating to the inclination of the cylinder in a plane parallel to the pivot axis and the longitudinal axis.

(88) A hydraulic cylinder assembly, wherein first and second bending sensors are mounted either side of the hydraulic cylinder.

(89) A hydraulic cylinder assembly , wherein the or each bending sensor comprises a strain gauge.

(90) A hydraulic cylinder assembly, wherein at least one end of the hydraulic cylinder is provided with an eye which defines the pivot axis.