The present disclosure relates to controlling the infeed throat opening of a wood chipper that is used for processing brush and logs, and which has a sensor to sense when incoming dense material exceeds a selected height, and causing the feed throat to open momentarily in order to feed a log or other dense, solid material into a chipper rotor. As shown, an upper feed roller is raised to open the throat. After a timed interval the lifting force is released to permit the upper feed roller to bear against the material being fed with the normal spring force applied to the feed roller.
Various brush chippers have been advanced, and they generally have a powered chipper rotor that will disintegrate brush, logs or the like that are fed into a chipper rotor. Prior chippers have springs or actuators to provide a force bearing on incoming feed material, and have in some manner sensed the load on or speed of the rotor or chipper wheel and provided for various corrective action when the load exceeded a certain level. The sensors used may be sensing drive engine speed, hydraulic pressure, if the unit is driven with hydraulic motors, or other sensors that sense when the chipper disc or rotor starts to slow. In addition there are automatic reversing drives which will reverse the in-feed roller direction of rotation when the load on the chipper rotor exceeds a certain load level.
Additionally, many of the existing brush chippers have operator controls to permit the operator to manually move or raise an in-feed roller to accommodate large material that normally would not be fed because of the throat size of the in-feed passage.
The present disclosure provides for a control to adjust the in-feed opening of a chipper when oversize material is being fed in. As shown, the space between a pair of in-feed members of a chipper is increased in response to receiving a signal indicating that the height of the in-feed material relative to a reference is greater than a selected amount measured in the direction of movement of a movable in-feed member. A first moveable in-feed member, a feed roller as shown, is moved relative to a second in-feed member or roller in response to the signal. The movement of the first in-feed member increases the spacing between the pair of in-feed members for a selected short period of time to permit the large size material to be fed into the chipper disc or rotor, after which the moveable member is released from the force separating the feed members and the first in-feed member is held against the material being fed by springs in a normal manner.
As shown, an ultrasonic sensor measures the distance from a reference position to the top of an item being fed into the in-feed members, (called rollers) of the chipper, and provides a signal indicating that a selected distance of the material top from the reference has been exceeded to a controller that controls various operations of the chipper. The controller sends a signal to actuate an actuator to move the first moveable in-feed roller away from the second in-feed roller. The moveable roller is mounted on a framework that is moved by the actuator. The actuator shown is a hydraulic actuator that has an outer cylinder with a base that is mounted on a support fixed relative to the frame of the chipper, and a piston rod is extendible to move the moveable roller away from the second roller, which second roller, in the form shown is a stationary axis roller.
Additional controls that may be provided in certain aspects of the present disclosure include, if desired, a switch that will provide for changing the in-feed roller speed to accommodate brush chipping or log chipping. Such a switch can also be used to control the activation or deactivation of the sensor actuated in-feed roller lift system. When the higher feed roller speed is selected, which is for chipping brush, the system including the sensor and actuator for moving the first infeed roller system will be deactivated, but when logs are being fed into the chipper, and a lower feed roller speed is selected, the feed roller moving or lift system, including the ultrasonic sensor, will be activated. Generally speaking, brush has smaller diameter limbs, and it is not very dense, and if the feed roller moving system is activated, the sensor could provide a false signal and by then separating the feed rollers, the feed rollers could lose their grip on the brush being fed.
The moveable feed roller is preferably moved proportionally to the height signal being provided by the sensor. Closed loop control can be established by providing a linear sensor on the cylinder or actuator that lifts the moveable feed roller to measure the actual amount of extension of the piston rod of the actuator, and providing a signal to the controller.
The chipper shown may have additional conventional controls for sensing engine speed of the engine driving the chipper rotor, and controls for reversing the feed rollers when the chipper rotor is loaded excessively, as well as providing necessary pressure sensors on the in-feed rollers for reversing the in-feed rollers if there is a jam. Controlling reverse and forward movement of the feed rollers in response to hydraulic pressure levels is a known control and can be used along with the present device, which ensures that the feeding of logs, in particular, will be possible by having the moveable feed roller moved to provide a larger feed throat when a large log is being fed.
In the form shown, the brush or logs are fed manually, but suitable feed conveyors can be provided if desired for moving materials to be chipped and obtaining the benefits of the present in-feed system.
A brush or log chipper is indicated generally at 10. As shown, it can be a mobile unit that has a trailer schematically shown at 12 for transporting it from place to place, and the trailer would support an engine 16, which is shown only schematically in
The chipper rotor 14 is conventional and is positioned inside a rotor or disc housing 18, that has a discharge chute 20 that can be directed to discharge the chips formed in a suitable direction, as is well known. The chipper rotor 14 can be of any desired form, and is driven so that it will chip brush or logs that are fed into the chipper rotor along a feed platform 22. The feed platform 22 is part of a feed housing 24 that is shown schematically in
A moveable in-feed member or roller 36 is positioned above the stationary axis in-feed roller 26, in the form shown and is mounted on a slide 40 on the side shown in
The in-feed mechanism shown comprises infeed members formed by powered rollers, which are commonly used in chippers. Instead of rollers, a short aggressive conveyor can be mounted for moving material to the chipper rotor. Powered rollers that rotate about vertical axis can be used as well, with one roller being movable horizontally to change the throat size.
The frame 32 of the chipper includes a fixed cross plate 56 (
The base of the clevis of piston rod 68 is made so that it will stop against an upper end 63 of the actuator 62, and this provides a fixed stop for stopping movement of the upper or moveable feed roller 36 toward the lower or stationary axis feed roller 26. The upper moveable feed roller 36, and the slides 42 and 46 as well as the lift bracket 50 are urged toward this stopped position by a pair of springs 74, one on each of the opposite sides of the chipper frame. The springs 74 have first ends anchored in respective brackets 76 that are connected to the lift bracket 50, and the other ends of the spring 74 are connected to adjustable rods 78 that are mounted on fixed brackets 80 on the frame 32 of the chipper. Springs 74 exert a resilient biasing force tending to urge the upper or moveable feed roller 36 toward the stationary axis feed roller 26. Again the most downward position, or where the moveable feed roller is the closest to the stationary axis feed roller, is determined by the positioning of the actuator 62 and the stopping of the piston rod 68 in its inward travel. This position defines the smallest throat size for the chipper in-feed.
It can be seen that extension of the piston rod 68 will cause the bracket 50 to be lifted through the bracket arm 70 and cross plate 52, and this in turn will lift the slides 40 and 46 and the moveable roller 36 in a direction away from the stationary axis feed roller 26.
As illustrated in
In order to accommodate large logs such as that shown at 88, an ultrasonic sensor 90, which is mounted onto a bracket 92 that in turn is attached to the top wall 25 of feed housing 24 (
Controller 94 includes a circuit to provide a time signal having a length that is proportional to the signal from the ultrasonic sensor. In other words, the greater the height signal, the longer the valve 96 will keep the moveable roller raised. One also can have an adjustable timer for limiting the time of actuation of the valve 96. For example, after 3 seconds or other selected time interval, or when the proportional time signal expires, the control valve 96 can be actuated to release the pressure at the base end of the hydraulic actuator 62 and place the valve 96 in a “float” position. The float position will permit oil to flow out of the base end of the actuator and into the rod end of the actuator so that the springs 74 will exert a down force on the feed roller 36. The initial raising of the feed roller 26 will be sufficient so an operator can place the log 88 in a position where the rollers will drive it toward the chipper rotor. The moveable feed roller 36 will be raised sufficiently to permit the log to enter between the feed rollers and be moved to be disintegrated by the rotor 14 of the chipper.
The controller 94 includes a manual switch shown schematically at 100 that controls a valve 104 to provide different flows of hydraulic fluid for driving the hydraulic motors 30 and 44 for the feed rollers selectively at a high speed or at a low speed. The higher speed is utilized for brush, with less dense material and branches, and the roller lift system, and ultrasonic sensor 90, will be disabled by the controller when the higher feed roller speed is selected. When the lower feed roller speed is selected with switch 100, for feeding in logs, the ultrasonic sensor 90 and the controls for the valve 96 to the lift actuator 62 will be enabled or activated, in the form disclosed.
The sensor 90 and the lift system can be disabled and the valve 96 left in its float position as brush or very loose material is being fed, for example, because branches and twigs can collapse together. If piles of branches and brush reach the sensing position of the ultrasonic sensor, the sensor could signal that the moveable feed roller should be raised. The feed rollers could lose their grip as the branches and twigs collapse. The lift of the movable feed roller is only for a short time span, as disclosed, so the rollers again will move together and usually there is no problem with feeding even if the lift system is operating at a high selected speed.
The chipper controls include manual controls, where an operator can operate the lift actuator 62 by manually extending the piston rod or manually placing the valve for actuator 62 into a “float” position. The manual controls will permit an operator to add a force on the movable roller in the direction toward the stationary roller that is greater than the spring loading force, if desired. By setting a relief valve in the line to the rod end of the actuator at a desired level or by providing an accumulator in the line, the hydraulic lift actuator can provide a bias force to return the movable roller to its reference position. Also the chipper includes sensors for engine speed, hydraulic pressure or the like to either stop, reverse and again start the feed wheels or rollers in accordance with conventional operation.
A closed loop control system can be provided to the controller 94 for controlling the amount of the extension of the piston rod 68 of the actuator. This can be done with a linear sensor, and these sensors are well known. Such a piston rod extension sensor is shown schematically at 110. This is shown only schematically because the sensors can be built right into the cylinder. The controller 94 receives the signal from the sensor 90 indicating the height of the incoming log, and operates valve 96 to move cylinder to raise the moveable roller, and the signal from sensor 110 is compared with the signal from sensor 90 to insure the cylinder 62 extends the proper amount. A closed loop control also insures that the extension of the actuator rod 68 does not exceed the material height signal from the ultrasonic sensor. When a closed loop system is used, the sensor in the actuator can be used to “arm” or make ready the height detecting system, when the movable feed roller returns to its working or reference position closest to the stationary roller.
If needed the controller can be programmed to provide additional time if the incoming log is not fed into the feed rollers during the proportional time or fixed time from the timer. If the time that the controller sets for pressurizing the base end of the actuator expires, and the sensor 90 still senses excessive height of the incoming log, the controller could provide an extra time period for keeping the moveable roller raised. A manual push button also could be used to extend the time the moveable roller is raised by the actuator 62.
It should also be noted that the control of the actuator could be a simple on/off valve that pressurized the actuator when the sensor signal indicated presence of high material and released the actuator when the signal ceased.
Although the present invention has been described with reference to preferred embodiments, workers skilled in the art will recognize that changes may be made in form and detail without departing from the spirit and scope of the invention.