EP0513479A1 - Impact breaker and method for controlling its working gap - Google Patents

Abstract

An impact breaker having at least one rotor (4) which can be driven, is rotatably mounted in a housing and is provided with impact rods is proposed, the housing containing a charging mouth (3) for the material to be broken up. Inside the housing, at least one impact mechanism (6) with adjustment drive is provided in the form of a hydraulic cylinder. In order to change the width of the charging mouth, an approximately vertically displaceable cross-member (10) is mounted on the charging side upstream of the first impact mechanism (6), which cross-member (10), by being raised, can eliminate blockages possibly occurring in this region. In the region of the first impact mechanism (6), a further adjustment device (15) is provided on the charging side, which device is capable, when the said impact mechanism (6) is raised, of eliminating jamming in the upper mouth space area. In order to be able to eliminate blockages in the lower mouth space area above the rotor, the adjustment drive (15, 16) provided here for the gap adjustment is simultaneously also used for raising the impact mechanism (6). Analogously, other impact mechanisms (7) fitted downstream can also be provided with this device. <IMAGE>

Description

The invention relates to an impact crusher with at least one rotor rotatably mounted in a housing, drivable and provided with blow bars, a feed mouth for the material to be broken, at least one impact mechanism mounted pivotably in the housing, including adjustment drive, facilities for changing the width thereof being provided in the area of the feed mouth .

DE-A 39 11 086 discloses an impact crusher of the generic type. A control device for controlling the first adjustment drive is provided. At the outlet of the crusher, a sorting device known per se is arranged, which separates the oversized grain fraction from the normal grain fraction, feeds a first weighing device for the normal grain fraction and a second weighing device for the oversize grain fraction, the output signals of which are fed into the control device and the control device via the first adjustment drive The position of the monoblock in relation to the impact circle of the impact roller changes when the ratio of oversize to normal grain deviates from a predetermined value. Upstream of the first monoblock is a pivotable plate which is pivotally mounted in the area of the mouth's entry opening. The free end of the plate lies loosely on a stop of the first monoblock, the plate being biased downwards by means of a spring. When the first monoblock is actuated in the area of the first adjustment drive, not only the monoblock but also the plate displaced thereon is actuated in a manner that expands the feed mouth. The disadvantages of this device are essentially due to the fact that larger materials to be broken into the feed mouth can jam between the monoblock and the adjustable plate, and even when the monoblock is adjusted, this jamming can no longer be released and the block must therefore be broken up from the outside . Since blockages often occur in the infeed area, a safe workflow cannot be guaranteed with the proposed change in width of the feed mouth.

The object of the invention is the further development of the impact crusher described in the generic part of the first claim to the extent that blockages on the one hand in the inlet area or in the or the grinding rooms and on the other hand above the blow bars of the rotor can be fixed safely and with simple means, without external intervention being necessary. In addition, a possibility is to be created to adjust the working gap between the impactor (s) and the blow bars of the rotor or to track them in the operating state in such a way that an optimal throughput with a maximum final grain can be achieved even with changing feed material.

This object is achieved according to the invention in that one of the devices is formed from a cross-member located in front of the impact mechanism arranged on the mouth side, which can be moved essentially in the vertical direction by means of an adjustment drive provided outside the housing.

Advantageous further developments of the subject matter of the invention can be found in the subclaims.

As a result of the traverse in front of the first impact unit, unlike the St.d.T. Independent operation of the individual facilities is possible, and if blockages occur, they can be reduced depending on external parameters, such as changing the power consumption of the crusher drive, belt scales or grain size change after sieving by appropriate actuation of the respective facility or facilities, without any intervention by outside is necessary.

If, for example, there is a block in the area of the feed mouth between the lower inlet plate and the crossbar, this is raised in a corresponding manner by means of the hydraulic cylinder, so that the clamped block is free and can fall into the crusher. The traverse is then moved back to its original position. The first impact unit is relocated so that it can be raised with a hydraulic cylinder. As a result, the grinding chamber is enlarged at the top, so that a block that is jammed here becomes free again and can fall onto the rotor. The impact device is then moved back to its starting position, the gap between the lower edge of the impact device and the blow bar essentially not being changed. If jams occur in the lower area of the first impact mechanism, this can be raised using the second adjustment drive. whereby the grinding chamber is enlarged below. The jammed block is released and can fall onto the rotor, whereby the impact mechanism is then also moved back to its starting position.

The device or devices can also be actuated in succession or together. The adjustment drive (s) in the lower area of the impact mechanism can also be used as an aid for adjusting the impact mechanism (s) (gap between monoblock and blow bar).

A method for adjusting the gap between the impactor (s) and the blow bars of the rotor and for actuating the devices is characterized in that a basic setting of the gap in relation to a predetermined final grain of a predetermined material is carried out in the factory and this basic setting is fed to a control, and that this basic setting can be changed or restored manually or automatically in the operating state, on the one hand, changes in the feed material or in the case of blockages in the feed mouth and, on the other hand, when wear occurs on the blow bars and the baffle plates of the impact units, by the control due to the changing Parameters actuated the necessary adjustment drives, in particular taking into account the measured values made available by the measuring probe. The hydro-mechanical unlocking of the mechanical clamping device is also triggered by the control, the probe detecting the stepless change in the travel of the piston rod and feeding it to the control via the measuring device. The clamping device is automatically locked again when the cylinder is at a standstill by returning the hydraulic pressure and automatically returning the mechanical clamping device to its starting position. In addition, there is the possibility that the control system, in addition to an automatic system, also contains manual setting means, such as potentiometers or the like, by means of which a stepless or predetermined intermediate setting of the devices can be brought about.

The fact that the adjustment drives are each equipped with a safety clamping device ensures that the cylinders cannot be adjusted in the rest position. The measuring probe causes the the adjustment drives and thus also the impact mechanism (s) can be moved continuously into any position. The electronic measuring device can be operated manually or automatically; Among other things, it has a feedback which indicates the respective position of the adjustment drive or the corresponding impact mechanism.

Various criteria can be used for automatic actuation, e.g. Current consumption of the drive motor from the crusher, quantity measurement of the different grain sizes after screening and belt scales.

Since, based on practical experience for materials to be broken, the wear rates occurring on the blow bars or the baffle plates of the impact units are largely known, these values can also be supplied to the control system, so that the impact unit (s) are automatically updated in the operating state at predetermined time intervals can be. Instead of hydraulic cylinders as adjusting drives, other drives such as spindles, hydraulic motors or the like can of course also be used.

Figur 1 -

Prallbrecher mit Einrichtungen zur Verstellung der Weite des Aufgabemauls bzw. der Mahlräume

Figur 2 -

Teildarstellung des ersten Prallwerks

Figur 1 zeigt einen Prallbrecher 1, der ein Gehäuse 2 beinhaltet, das mit einem Aufgabemaul 3 versehen ist. Im Gehäuse 2 ist ein Rotor 4 samt Schlagleisten 5 drehbar verlagert. Oberhalb des Rotors 4 sind zwei Prallwerke 6,7 angeordnet, die rotorseitig mit Prallplatten 8,9 versehen sind. Dem Prallwerk 6 vorgeschaltet ist eine Traverse 10, die zwischen Platten 11,12 geführt ist und maulseitig mit einem Verschleißelement 13 versehen ist. Die Traverse 10 wird mittels eines Verstellantriebes 14 in Form eines Hydraulikzylinders im wesentlichen in vertikaler Richtung verstellt, um auf diese Art und Weise eine Änderung der Einlaufweite des Aufgabemaules 3 herbeiführen zu können. Im maulseitigen Bereich des ersten Prallwerks 6 ist ebenfalls ein Verstellantrieb 15 in Form eines Hydraulikzylinders vorgesehen, der bei Betätigung ebenfalls zur Weitenänderung des Aufgabemaules 3 führt. Ein weiterer Verstellantrieb 16 im Bereich des ersten Prallwerks übt einerseits die Funktionen Weitenänderung des Aufgabemaules 3 im unteren Mahlraumbereich und andererseits die Einstellung des Spaltes a zwischen der unteren Kante 18 der Prallplatte 8 sowie der Schlagleiste 5 aus. Analoges gilt für das zweite Prallwerk 7, das ebenfalls einen Verstellantrieb 17 in Form eines Hydraulikzylinders aufweist. Die die Hydraulikzylinder 16 und 17 verriegelnden Sicherheitseinrichtungen sind in Figur 2 angedeutet und beschrieben. Der hier zwischen den Schlagleisten 5 und den Prallplatten 9 sich einstellende Spalt ist mit b bezeichnet.The invention is illustrated in the drawing using an exemplary embodiment and is described as follows. Show it:

Figure 1 -

Impact crusher with devices for adjusting the width of the feed mouth or the grinding rooms

Figure 2 -

Partial representation of the first impact system

FIG. 1 shows an impact crusher 1 which contains a housing 2 which is provided with a feed mouth 3. A rotor 4 together with blow bars 5 is rotatably displaced in the housing 2. Above the rotor 4, two impact units 6, 7 are arranged, which are provided on the rotor side with baffle plates 8, 9. A cross member 10 is connected upstream of the impact mechanism 6, which is guided between plates 11, 12 and is provided with a wear element 13 on the mouth side. The crossmember 10 is adjusted essentially in the vertical direction by means of an adjustment drive 14 in the form of a hydraulic cylinder, in order in this way to change the inlet width of the Task mules 3 can bring about. An adjustment drive 15 in the form of a hydraulic cylinder is also provided in the mouth-side region of the first impact mechanism 6, which also leads to a change in the width of the feed jaw 3 when actuated. Another adjustment drive 16 in the area of the first impact unit performs the functions of changing the width of the feed mouth 3 in the lower grinding chamber area on the one hand and the setting of the gap a between the lower edge 18 of the impact plate 8 and the blow bar 5 on the other hand. The same applies to the second impact mechanism 7, which also has an adjustment drive 17 in the form of a hydraulic cylinder. The safety devices locking the hydraulic cylinders 16 and 17 are indicated and described in FIG. The gap between the blow bars 5 and the baffle plates 9 is denoted by b.

The function of the impact crusher 1 is roughly as follows:
Material to be broken is fed via the inlet chute 19 and falls onto the rotor 4 via the feed chute 20. Here, the material to be broken is gripped by the blow bars 5 and at least partially already crushed. Sufficiently shredded material passes through the gap a between the lower baffle plate edge 18 and the blow bar 5 into the area of the second baffle unit 7, where further shredding is effected in an analogous manner. The material that has been sufficiently shredded here is discharged downwards through the gap b. Material that has not yet been sufficiently comminuted is thrown against the baffle plate 8 by the blow bars 5, where further comminution takes place. The material is moved in the first grinding chamber 21 until it reaches the second grinding chamber 22 through the gap a.

Since the feed material generally has a wide variety of grain sizes and is often stacked one above the other in blocks, it can happen that individual blocks 23, 24, 25 get stuck at different points in the first grinding chamber 21 and thus lead to blockages. If, for example, a block 23 is jammed between the chute 20 and the crossbeam 10, the parameters of the impact crusher change. Since there is no or only a small supply of material, the current consumption of the rotor drive changes (not shown). At the same time, changes occur in the screened Grain on because no or less material is penetrated. Based on one or more external parameters, the location of the constipation can be localized and appropriate countermeasures taken. In the event of a blockage in the area of the crossbeam 10, it is pulled up by the hydraulic cylinder 14 by a predetermined amount (for example 200 mm) and the clamped block 23 can fall onto the rotor 4 via the chute 20 and be shredded there. Once the blockage has been removed, the crossbeam 10 is automatically moved back into its starting position. In the operating state, the lower edge 26 of the wear element 13 is approximately at the same level as the upper edge 27 of the baffle plate 8, so that a smooth transition of the material to be discharged is ensured without larger chunks being able to get stuck in the gap between the wear element 13 and the baffle plate 8 .

If the blockage occurs in the upper area of the impact mechanism 6, various operating parameters change here too, which lead to the localization of the blockage. The hydraulic cylinder 15 is actuated and the impact mechanism 6 is pivoted about the pivot point 28 of the lower suspension of the hydraulic cylinder 16, the gap a being changed only within the tolerances customary here, without this resulting in a change in the end grain. Once the blockage has been removed, the block 24 falls onto the rotor 4 and is comminuted as before, the impact mechanism 6 being moved back to its starting position.

If the blockage occurs in the lower region of the impact mechanism 6, the hydraulic cylinder 16 is actuated due to the changing operating parameters and the impact mechanism 6 is pivoted about the pivot point 29 of the upper hydraulic cylinder 15. If the blockage is removed, the block 25 falls on the rotor 4 and is crushed.

The same applies to the downstream monoblock 7, which can also be actuated via the hydraulic cylinder 17 in the event of blockages in the second grinding chamber 22, although blockages occur less frequently here.

The actuation of the hydraulic cylinders 14-17 can be carried out individually or together.

The setting of the gap a and / or b or its readjustment in the operating state also takes place on the basis of the changing external parameters. For example, the sieved end grain changes when there is wear on the blow bars 5 or the baffle plates 8 or 9, the gap a or b being automatically adjustable again by means of a controller on the basis of predetermined parameters. When the feed material changes, the gap a or b can be changed either manually or automatically in order to do justice to the corresponding other material properties, the operating parameters already mentioned also being taken into account here. The same applies to desired changes in the final grain size with the same feed material, manual adjustments of the gap a or b being possible, for example, by means of a potentiometer.

FIG. 2 shows a partial representation of the first impact mechanism 6 together with the impact plate 8 and adjustment drives 15, 16. The adjustment drive 16, which is designed as a hydraulic cylinder, contains, as additional safety devices, an only indicated commercially available hydro-mechanical clamping device 30 and a measuring probe 31 in the form of an inductive displacement sensor. The safety clamping device 30 ensures that the hydraulic cylinder 16 cannot be adjusted in the rest position. Should the hydraulic cylinder 16 move, i.e. retracted or extended, this clamping device 30 opens automatically by hydraulic action (not shown), so that the piston rod 32 can be moved in a corresponding manner, monitored by the inductive displacement sensor 31. Once the corresponding adjustment process has been carried out, the clamping device 30 is automatically closed again by hydraulic relief and the hydraulic cylinder 16 is mechanically fixed. The inductive displacement sensor 31 is connected to an electronic measuring device, not shown. With this system, the hydraulic cylinder 16 together with the impact mechanism 6 can be moved continuously into any position. The electronic measuring device can be operated manually or automatically. Among other things, a feedback indicating the respective position of the hydraulic cylinder 16 together with the impact mechanism 6.

A basic setting of the gap a or b for a predetermined material and a predetermined final grain size is set in the factory; for example for the material limestone with a peripheral speed of Rotor 4 of 35 m / s and a final grain size 0/60 mm with 70% 0-20 mm grain, the gap a of the first impact mechanism 6 is set to 40 mm and the gap b of the second impact mechanism 7 to 20 mm. Depending on the material properties of this material, the wear on the blow bars 5 and the baffle plates 8, 9 is essentially already known, so that the control system is able to automatically restore the gap a or b at predetermined time intervals without it being too Collisions of the striking elements 8 and 5 or 9 and 5 comes. In the case of a changing material or a desired grain change of the same material, there is the possibility of adjusting the impact mechanisms 6 and 7, which in turn can be carried out as a function of the changing operating parameters.

Claims (15)

Impact crusher with at least one rotor which is rotatably mounted in a housing and is provided with blow bars, a feed mouth for the material to be broken, at least one impact mechanism which is pivotably mounted on the housing together with an adjustment drive, facilities for changing the width thereof being provided in the area of the feed mouth, characterized in that one of the devices is formed from a crossbar (10) arranged in front of the impact mechanism (6) arranged on the mouth side, which can be moved essentially in the vertical direction by means of an adjustment drive (14) provided outside the housing (2). Impact crusher according to claim 1, characterized in that the cross member (10) is provided with wear elements (13) on the mouth side. Impact crusher according to claims 1 and 2, characterized in that the adjustment drive (14) is formed by at least one hydraulic cylinder. Impact crusher according to claims 1 to 3, characterized in that the crossmember (10) extends essentially over the width of the rotor (4) and is held and guided between plates (11, 12). Impact crusher according to claims 1 to 4, characterized in that the free end of the crossmember (10) or the wear elements (13) in the operating position is set to approximately the same level as the corresponding edge (27) of the impact mechanism (6) connected downstream. Impact crusher according to claims 1 to 5, characterized in that the free end of the crossmember (10) or the wear elements (13) in the operating position of the corresponding edge (27) of the downstream impact mechanism (6) narrows slightly into the feed mouth (3) is upstream. Impact crusher according to claims 1 to 6, characterized in that a further device for changing the width of the feed mouth (3) is formed by an adjustment drive (15) known per se and interacting with the crossbar (10) in its area on the feed side is. Impact crusher according to claims 1 to 7, characterized by at least one further device for changing the width of the grinding chamber (s) (21, 22), which is formed by the adjustment drive (16, 17) of the impact unit (s) (6, 7). Impact crusher according to claims 1 to 8, characterized in that the actuation of the devices (10, 15-17), each individually or in combination, by external parameters, such as Grain size change after sieving, belt scales, changes in the current consumption of the crusher drive or the like, can be brought about. Impact crusher according to claims 1 to 9, characterized in that the adjusting drive (16, 17) of the impact mechanism (s) (6, 7) is formed by at least one hydraulic cylinder, the piston rod (32) of which has a hydro-mechanical clamping device (30 ) can be determined. Impact crusher according to claims 1 to 10, characterized in that the clamping device (30) can be unlocked hydraulically. Impact crusher according to claims 1 to 11, characterized in that the hydraulic cylinder (16, 17) is equipped with a measuring probe (31), in particular an inductive displacement sensor, which is connected to an electrical measuring device. Method for setting the gap between the impactor (s) and the blow bars of the rotor and for actuating the devices according to one or more of claims 1 to 12, characterized in that a factory setting of the column (s) (a, b) is related made to a given final grain of a given material and this basic setting is fed to a control, and that this basic setting is manually or automatically in the operating state on the one hand when there are changes in the feed material, changes in the final grain or blockages in the feed mouth (3) and / or in that Grinding rooms (21, 22) and, on the other hand, when wear occurs on the blow bars (5) and the baffle plates (8, 9) can be changed or restored on the basis of external parameters by the control unit making the necessary adjustment drives (14-17 ), in particular taking into account that by the measuring probe (31) for Ve provided measured values, actuated. A method according to claim 13, characterized in that the control unit triggers the hydraulic unlocking of the clamping device (30), the probe (31) detects the stepless change in the travel of the piston rod (32) and feeds it to the control unit via the measuring device and the clamping device (30) when stationary of the cylinder (16, 17) is locked automatically. Method according to claims 13 and 14, characterized in that the control means, e.g. Potentiometer, by means of which a continuous or predetermined intermediate setting of the devices (10, 15-17) is carried out manually.

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