DE2003211B2 - Paver - Google Patents

Description

The invention relates to a road paver with a storage container for the paving material, the by means of conveyor belts can be supplied to augers, and with sensors arranged on the augers to control the flow of ceiling construction material through the conveyor belts and the augers to the screed.

A well-known road paver of this type is the »BARBER-GREENE black paver, TYPE SB-30 «. In this known paver, the control of the paving material flow is such designed so that this automatically controls the conveyor and the augers on each side independently of one another starts and stops. This is a control that only switches off or on Switching on the conveyor belts and the augers causes. With this known control, the Ceiling construction material flow to the screed interrupted. As a result of turning on the conveyor belts and As the amount of floor construction material increases, the screed becomes an increasingly larger one Opposed resistance, which gradually decreases again after switching off the steady working speed of the paver will be affected to different compaction of the street pavement.

The invention has for its object to improve the known paver so that the ceiling building material flow is continuously controlled according to the requirements at the installation site.

According to the invention, this is achieved in that each sensor is connected to an electrical switching element is that continuously outputs a voltage proportional to the sensor position, that the electrical Switching element is switched on in a bridge, which continuously controls an actuator with which continuously the conveying speed of the conveyor belt and the distribution screw or continuously the Material quantity discharge from the storage container is controlled on the conveyor belt.

The continuous influx of ceiling building materials achieved in this way to the screed ensures a more even paving speed of the paver and thus a more even ceiling density.

A particularly simple structure results when according to a further embodiment of the paver according to the invention, the electrical switching elements potentiometer are. In one embodiment of the road finisher according to the invention, each can advantageously Switching element to be switched on with a feedback potentiometer in the bridge, which relay one Relay slide controls, which is switched into the feed line of a hydraulic actuating piston forming the actuator is, which adjusts the delivery rate of a pump, which in turn has a hydraulic motor for the Conveyor belt and the feed screw feeds, and that the actuating piston with the feedback potentiometer is mechanically connected.

According to a further embodiment, each switching element can advantageously be switched into the bridge with a feedback potentiometer, which controls a solenoid valve which is switched into the feed line of an actuating piston forming the actuator which controls a control gate between the hopper and the conveyor belt, and that the Control gate is mechanically linked to the feedback potentiometer.

The invention is illustrated by means of exemplary embodiments with reference to the figures of the drawing explained. It shows

F i g. 1 is a plan view of a paver constructed in accordance with the invention; F i g. FIG. 2 is a side view of the FIG. 1 illustrated paver,

F i g. 3 shows a schematic representation of another embodiment and

F i g. 4 is an electrical circuit diagram of a circuit that can be used in the invention. F i g. 1 shows a road paver, which is generally designated by 10. The road paver 10 has a frame 11 which carries a Vorratsbehäl ter 12 which holds a supply of the ceiling construction

The bottom of the storage container is open, so that the ceiling construction material is fed to two conveyor belts 13 and 13a within the storage container can be. The ceiling construction material from the storage container 12 is picked up by the conveyor belts 13 and 13a and conveyed in the direction of arrow 46 to a delivery area 14.

In the delivery area 14 is in the middle of the paver a projecting housing 16 is provided. Zwv.'i augers 17 and 18 are respectively carried at one end by the housing 16. The other end of the auger 17 is rotatable by a Support plate 19 and the other end of the distribution auger 18 carried by a support plate 20. the Support plates 19 and 20 are on the sides of the paver 10 attached.

Two guides 21 and 22 are arranged next to the support plates 19 and 20. The feelers are designed in Gerart and arranged to float or move upward when the amount of paving material is large enough in the delivery area to engage the sensors. With the sensor 21 is a Switching element 23 is connected, and a switching element 24 is connected to the sensor 22. The switching elements 23 and 24 are variable resistances according to the positions of the sensors.

The paver 10 has a drive 26, for example an internal combustion engine or a Diesel machines with wheels or similar drive means, which are not shown, are connected to the paver in the direction of arrow 27 when the paver is used to deliver paving material to the delivery area 14 submit. A floating screed 28 is arranged behind the augers to allow Leveling and compacting ceiling construction soft. When the ceiling construction material is fed to the delivery area 14 If there is asphalt, the screed 28 will smooth the asphalt.

During the operation of the paver 10, the paving material is transported by the conveyor belts 13 and 13a fed to the delivery area 14. In the delivery area 14, the ceiling construction material is then in opposite directions Directions transverse to the paver by the augers 17 and 18 moved. if the ceiling construction material reaches the end of the augers 17 and 18 in the area of the support plates 19 and 20, in this way the quantities of the ceiling construction material are sensed by the sensors 21 and 22. The movements the sensors 21 and 22 generate changes in resistance within the corresponding switching elements 23 and 24. These changes in resistance are used to increase the speed at which the ceiling material is conveyed To control the screed via the delivery area 14. This conveying speed corresponds to the need the installation point.

The storage container 12 receives the ceiling construction material 25, which is attached to the built-in parts via the conveyor belts 13 and 13a and via distribution screws 17, 18 is discharged. A deflector plate 30 is in the bottom of the Reservoir 12 provided to prevent that ceiling material accidentally from the reservoir on the Front ends of the conveyor belts flow onto the road surface in front of the paver. The conveyor belts 13, 13a are carried by rollers 31 and 32. The rollers 32 are connected to a drive to the conveyor belts 13 and 13a and the augers 17 and 18 to drive.

In Figure 2, a control device is shown with which controls the flow of paving materials according to the requirements at the installation site of the road paver will. The sensor 21 senses the height of the ceiling construction material, for example the asphalt, from the auger 17 is accumulated at its outer end. The sensor 21 controls the switching element 23. The switching element is a potentiometer, a differential transformer or any other device, which generates a control signal which indicates the position of the sensor 21. The control signal then becomes one Bridge 50 supplied. A selection switch 34 is connected to bridge 50. Electric voltage becomes the bridge 50 via lines 51 and 52. The electrical voltage is supplied by the generator of the Drive 26 derived.

The output of the bridge 50 is connected to two solenoids 53 and 54 which control the operation of a relay slide 55. The relay slide 55 receives hydraulic fluid from a container 56 and controls the direction of flow of the hydraulic fluid that is fed to a hydraulic actuating piston 57. The actuating piston 57 has an extendable piston rod 58. Movement of the extendable piston rod 58 controls operation one ^rl by _r . 59 by the movement of an adjusting lever 60 for a swash plate. The pump 59 has a shaft 61 which is in drive connection with the drive 26. Hydraulic fluid is fed from the pump 59 to a hydraulic motor 62 via lines 63. The output of the hydraulic motor 62 is connected to a reduction gear 64, which in turn is connected to a shaft 66.

At one end of the shaft 66, a sprocket 67 is attached, which receives a drive chain to the Rotation of one of the augers 17 or 18 to control. The other end of the shaft 66 has a sprocket 68, which receives a drive chain to move the conveyor belts 13 or 13a steer. The speed of the augers 17 and 18 is therefore proportional to the linear conveying speed the conveyor belts 13 and 13a.

The in F i g. The control device shown in FIG is supplied and which is then promoted transversely to the direction of travel of the paver, namely to sensors 21 and 22. Manual operation can be set with the selection switch 34 so that the operating personnel can perform the control of the ceiling construction material flow if an automatic operation is not wanted.

If, during automatic operation, the amount of ceiling construction material supplied to the delivery area 14 and which is sensed by the sensor 21 is less than the required amount, a difference signal generated by bridge 50 to control the operation of solenoids 53 and 54. This will make the movement the extendable piston rod 58 of the actuating piston 57 is controlled, whereby the movement of the adjusting lever 60 is controlled to increase the amount of hydraulic fluid supplied to the hydraulic motor 62 via the pump 59 is supplied. The increased supply of the hydraulic quantity increases the speed of the hydraulic motor increased by the feed rate of the conveyor belts and by the speed of the distribution auger raise. As a result, more ceiling building material is fed to the delivery area 14 until the sensors determine that the building materials menu. which is fed is the same

like the one required for the road surface. If the sensor 21 detects that more ceiling fabric than necessary is supplied, the bridge 50 generates a differential signal by which the speed of the hydraulic motor 62 is reduced in order to reduce the amount of ceiling construction material which is supplied to the delivery area 14 is fed. A feedback potentiometer 73 is connected to the adjustment lever 60 and to the bridge 50, to indicate that the required change in the ceiling construction material funding is being carried out, and to to maintain the required flow rate until a corresponding determination is made by the sensors. The same operational relationship exists between the sensor 22 and the auger 18.

In Fig. 3 another embodiment is shown, in which the switching element 23 is connected to a bridge 33 via a selection switch 34. The selection switch has a switch-off position, an automatic position and a manual operating position. the Bridge 33 is connected to a solenoid valve 36, which in turn controls the amount of hydraulic fluid controls, which is fed to an actuating piston 37. The actuating piston 37 blows an extendable piston rod 38 which is connected to a control gate 39. The position of the control gate 39 controls the amount of ceiling building material 25, which is discharged from the storage container 12 onto the conveyor belts.

The solenoid valve 36 is an electrically operated hydraulic control valve that operates with a pump 40 connected is. The pump 40 is connected to a reservoir 41 in order to extract hydraulic fluid feed the container to the solenoid valve 36 <_n. the Hydraulic fluid is then fed to a second container 42 from the solenoid valve 36.

In the illustration in FIG. 3, the feedback potentiometer 73 is connected to the control gate 39 and is also electrically connected to bridge 33 as a feedback element.

The control arrangement enables manual setting which is carried out by means of a potentiometer 43. That Potentiometer 43 is connected to selection switch 34 via line 44, specifically to the manual control position this selector switch 34. When the selector switch 34 is in the automatic position is located, then the paver is automatically according to the need in the delivery area 14 through the sensors 21 and 22 are controlled, which generate differential signals to the conveyor belts and the augers control according to the need. The pump is mechanically connected to the resistance value of the Feedback potentiometer 73 to control the leveling of the bridge and to control the operating level of the paver to maintain the new rate of delivery of the ceiling building material to the delivery area 14. It will So an electrical balance is created when the ceiling material feed is equal to the need.

In Fig. 4, there is shown one embodiment of an electro-mechanical controller that can be used to control the paver. The in F i g. The control circuit shown in FIG. 4 has left and right sensors 70 and 71 which serve to control the operation of the separate conveyor belts 13 and 13a. In this case the linear conveying speed of each conveyor belt corresponds to that of the corresponding augers 17 or 18. The sensor 70 has a potentiometer 72, both ends of which are connected to a feedback potentiometer 73 via lines 74 and 75. The potentiometers 72 and 73 have movable tapping arms 76 and 77 , which are connected to a servo device 78 via a line 79 and via the automatic contact one

ίο switch 81 and are connected via a line 80, to form a bridge. The pickup arm 76 has a feeler at one of the ends of the dispensing area and the tap arm 77 is connected to the adjusting lever 60 of the pump 59, as shown in FIG. 2 is shown. This connection can be used in the illustration in FIG. 3 lead to the control gate 39.

The lower connection of the potentiometer 72 is connected to a voltage source c via a line 75a. The movement of the tap arm 76 according to

Change in the amount of ceiling construction material to the corresponding Outside of the delivery area causes a shift of the bridge balance, and the servo device 78 causes actuation of one of the corresponding relays 82 and 83, for example the Relay 83, whereby a contact 85 is closed in order to operate the relay slide 55. With one actuation of the relay slide 55 are the actuating piston 57 and the piston rod 58 and the adjusting lever 60 operated by the pump 59 in order to change the amount of the ceiling construction material in a corresponding manner. An operation of the adjustment lever 60 also moves the pick-up arm 77 and effects an equilibrium setting the bridge opposite the tap arm 76 and an equilibrium setting of the servo device

78. The new setting of the feedback potentiometer 73 is therefore a feedback control, to set the sensors to a new ceiling material flow rate.

For manual control of the road surface

tigers is a manually changeable potentiometer 86 in the circle with the servo 78 and the Feedback potentiometer 73 turned on. The lower end of the potentiometer 86 is connected to a voltage source connected via a line 87 and is

connected to the lower terminal of the feedback potentiometer 73 via lines 87 and 75. The pick-up arm 89 is connected to the servo device 78 via the manual control contact of the switch 81. With this mode of operation, the bridge is matched to the desired amount of floor construction material what is determined by the operator. The in F i g. 4 control shown has a separate System, which extends from a potentiometer 91 via a switch 90 to a feedback

lungspotentiometer 101 and an adjusting lever 100 extended », to control the other distribution auger. Each system is using the same electrical voltage source and with the same hydraulic equipment 102 connected.

The rest of the FIGS. 3 and 4 correspond to the parts of FIG. 1 and 2.

For this purpose 3 sheets of drawings

Claims (4)

Patent claims: 1. Road paver with a storage container for the paving material, which can be supplied by means of conveyor belts augers, and with sensors arranged at the ends of the augers to control the paving material flow through the conveyor belts and the augers to the stripping screed, characterized in that each sensor (21, 22; 70. 71) is connected to an electrical switching element which continuously emits a voltage proportional to the sensor position, so that the electrical switching element is switched into a bridge (33, 50) which continuously controls an actuator with which the conveying speed of the conveyor belt (13 or \ 3ä) and the distribution screw (17 or 18) or continuously the amount of material is controlled from the storage container (12) to the conveyor belt (13 or 13a). 2. Paver according to claim 1, characterized in that the electrical switching elements Potentiometers (72,91) are. 3. paver according to claim 1 or 2, characterized in that each switching element with a feedback potentiometer (73 or 101) in the bridge (50) is switched on, which relay (82,83) of a relay slide (55) controls, which is in the feed line of a hydraulic actuator forming the The actuating piston (57) is switched on, which sets the delivery rate of a pump (59), which in turn have a hydraulic motor (62) for the conveyor belt (13 or 13a) and the distribution screw (17 or 18) feeds, and that the actuating piston (57) is mechanically connected to the feedback potentiometer is. 4. paver according to claim 1 or 2, characterized in that each switching element with a feedback potentiometer in the bridge (33), which is a solenoid slide (36) controls, which is switched into the feed line of an actuating piston (37) forming the actuator is, which is a control gate (39) between the storage container (12) and the conveyor belt (13 or 13a) controls, and that the control gate (39) is mechanically connected to the feedback potentiometer is.