This application is a §371 National Stage Application of PCT International Application No. PCT/EP2012/059975 filed May 29, 2012 claiming priority of EP Application No. 11170323.7, filed Jun. 17, 2011.
The present invention relates to an inertia cone crusher comprising an outer crushing shell and an inner crushing shell, said inner and outer shells forming between them a crushing chamber, the inner crushing shell being supported on a crushing head, said crushing head being rotatably connected to an unbalance bushing, which is arranged to be rotated by a drive shaft, said unbalance bushing being provided with an unbalance weight for tilting the unbalance bushing when it is rotated, such that the central axis of the crushing head will, when the unbalance bushing is rotated by the drive shaft and tilted by the unbalance weight, gyrate about a gyration axis, the inner crushing shell thereby approaching the outer crushing shell for crushing material in the crushing chamber. The invention also relates to a method for detecting tramp material in such an inertia cone crusher.
An inertia cone crusher may be utiliPMed for efficient crushing of material, such as stone, ore etc., into smaller siPMes. An example of an inertia cone crusher can be found in EP2116307. In such an inertia cone crusher, material is crushed between an outer crushing shell, which is mounted in a frame, and an inner crushing shell, which is mounted on a crushing head. The crushing head is mounted on a crushing head shaft. An unbalance weight is arranged on a cylindrical sleeve-shaped unbalance bushing encircling the crushing head shaft. The cylindrical sleeve is, via a drive shaft, connected to a pulley. A motor is operative for rotating the pulley, and, hence, the cylindrical sleeve. Such rotation causes the unbalance weight to rotate and to swing to the side, causing the crushing shaft, the crushing head, and the inner crushing shell to gyrate and to crush material that is fed to a crushing chamber formed between the inner and outer crushing shells.
It may happen that tramp material, for example metal parts that have fallen off upstream equipment, enters the crusher. Such tramp material will not be crushed by the crusher. Instead, the tramp material may damage or block the crusher, or pass through the crusher unnoticed and cause damage to downstream equipment.
It is an object of the present invention to solve, or at least mitigate, parts or all of the above mentioned problems. To this end, there is provided a method for detecting tramp material in an inertia cone crusher comprising an outer crushing shell and an inner crushing shell, said inner and outer shells forming between them a crushing chamber, the inner crushing shell being supported on a crushing head, said crushing head being rotatably connected to an unbalance bushing, which is arranged to be rotated by a drive shaft, said unbalance bushing being provided with an unbalance weight for tilting the unbalance bushing when it is rotated, such that the central axis of the crushing head will, when the unbalance bushing is rotated by the drive shaft and tilted by the unbalance weight, gyrate about a gyration axis, the inner crushing shell thereby approaching the outer crushing shell for crushing material in the crushing chamber, the method comprising
measuring at least one of a position and a motion of the crushing head;
obtaining, based on said measurement, a gyration value, said gyration value being indicative of at least one of an inclination of the gyration axis in relation to a reference line, a shape of the gyrating motion of the central axis of the crushing head, an amplitude of the gyrating motion of the central axis of the crushing head, and an inclination of the central axis of the crushing head in relation to a reference line;
comparing said gyration value with a gyration reference value; and
determining, based on said comparison, whether to issue a tramp material warning signal indicating the presence of tramp material in the crusher. This method allows for the detection of tramp material as it passes through the crushing chamber, such that appropriate actions for dealing with the tramp material may be taken.
According to an embodiment, the obtaining of said gyration value comprises low-pass filtering a signal from a sensor, and/or forming an average of values obtained from a sensor. Thereby, the gyration value may be cleared of any fluctuations caused by material to be crushed or the rotation of the crushing head.
According to an embodiment, said gyration reference value is determined based on a previously obtained gyration value. The method will thereby allow the detection of any seemingly unmotivated changes of the gyration behaviour of the crushing head, without the need for detailed a priori knowledge of an expected behaviour, said changes being indicative of a potential tramp material event.
According to an embodiment, said tramp material warning signal is issued based on the inclination of the gyration axis exceeding a reference inclination, and/or the amplitude of the gyrating motion of the crushing head passing a reference amplitude. These two conditions are relatively simple to detect, and are relatively strong indicators of the occurrence of a tramp material event.
The issuing of a tramp material warning signal may be used for triggering an action for remedying the effect of the presence of tramp material in the crushing chamber. Hence, according to an embodiment, the method comprises reducing, based on said tramp material warning signal, the RPM of the drive shaft and/or or the power delivered via the drive shaft. According to another embodiment, the method comprises issuing, based on said tramp material warning signal, an audible, visible, and/or sensory tramp material warning signal to an operator. According to yet another embodiment, the method comprises initiating, based on said tramp material warning signal, a tramp material removal procedure for separating the tramp material from a flow of crushed material downstream of the crushing chamber.
According to an embodiment, the method comprises determining, based on the gyration value, the location of the tramp material in the crushing chamber. This facilitates removing the tramp material by any automatic means. The method may also comprise indicating the location to an operator, such that the operator may remove it manually or take any other appropriate action.
According to an embodiment, the method comprises
obtaining a power value indicative of the power delivered to the crushing head via the drive shaft; and
comparing said power value with a power reference value, wherein said determination whether to issue a tramp material warning signal is also based on the comparison of the power value with the power reference value. The presence of tramp material in the crushing chamber also affects the power consumption of the crusher; hence, the power consumption can be used as a supplementary indicator, for increasing the reliability of the tramp material detection. The power reference value may, according to an embodiment, be determined based on a previously obtained power value. Hence, a sudden decrease of the power consumption may, provided that it is not motivated by a decrease of the flow into the crusher of material to be crushed, or of the RPM of the crusher, indicate that a tramp material event has occurred.
According to an embodiment, said gyration value is indicative of the inclination of the central axis of the crushing head. The inclination may be used for obtaining a tramp material indication when the crusher is in operation. Alternatively, or as a supplementary indication, a single value of the inclination may be used for determining the presence of tramp material in the crushing chamber when the crushing head is at rest. Thereby, any accidental re-starting of a stopped crusher having tramp material therein may be avoided.
According to another aspect of the invention, there is provided an inertia cone crusher comprising an outer crushing shell and an inner crushing shell, said inner and outer shells forming between them a crushing chamber, the inner crushing shell being supported on a crushing head, said crushing head being rotatably connected to an unbalance bushing, which is arranged to be rotated by a drive shaft, said unbalance bushing being provided with an unbalance weight for tilting the unbalance bushing when it is rotated, such that the central axis of the crushing head will, when the unbalance bushing is rotated by the drive shaft and tilted by the unbalance weight, gyrate about a gyration axis, the inner crushing shell thereby approaching the outer crushing shell for crushing material in the crushing chamber, the crusher further comprising a sensor for sensing at least one of a position and a motion of the crushing head, and a controller configured to obtain a gyration value and determine whether to issue a tramp material warning signal according to any of the methods described hereinbefore. Such a crusher is capable of detecting the presence of tramp material in the crushing chamber.
According to an embodiment, the inertia cone crusher comprises a power sensor for obtaining a power value indicative of the power delivered to the crushing head via the drive shaft, wherein the controller is configured to obtain a power value indicative of the power delivered to the crushing head via the drive shaft; and compare said power value with a power reference value, wherein said determination whether to issue a tramp material warning signal is also based on the comparison of the power value with the power reference value.
According to an embodiment, the inertia cone crusher further comprises a plurality of hatches for accessing the crushing chamber, each of said hatches allowing removal of tramp material therethrough; and means for indicating the location of tramp material to an operator, so as to assist said operator in selecting the correct hatch to open.
The invention is described in more detail below with reference to the appended drawings in which:
a-e are schematic top views, in cross-section, of a crusher as seen in the direction of arrows III-III of
The lower frame portion 6 supports an inner crushing shell arrangement 14. The inner crushing shell arrangement 14 comprises a crushing head 16, which has the shape of a cone and which supports an inner crushing shell 18, which is a wear part that can be made from, for example, a manganese steel. The crushing head 16 rests on a spherical bearing 20, which is supported on an inner cylindrical portion 22 of the lower frame portion 6.
The crushing head 16 is mounted on a crushing head shaft 24. At a lower end thereof, the crushing head shaft 24 is encircled by an unbalance bushing 26, which has the shape of a cylindrical sleeve. The unbalance bushing 26 is provided with an inner cylindrical bearing 28 making it possible for the unbalance bushing 26 to rotate relative to the crushing head shaft 24 about a central axis S of the crushing head 16 and the crushing head shaft 24. A gyration sensor reflection disc 27, the function of which will be described in more detail below, stretches radially out from, and encircles, the unbalance bushing 26.
An unbalance weight 30 is mounted on one side of the unbalance bushing 26. At its lower end the unbalance bushing 26 is connected to the upper end of a vertical transmission shaft 32 via a universal joint 34. Another universal joint 36 connects the lower end of the vertical transmission shaft 32 to a drive shaft 38, which is journalled in a drive shaft bearing 40. Rotational movement of the drive shaft 38 can thus be transferred from the drive shaft 38 to the unbalance bushing 26 via the vertical transmission shaft 32, while allowing the unbalance bushing 26 and the vertical transmission shaft 32 to be displaced from a vertical reference axis C during operation of the crusher.
A pulley 42 is mounted on the drive shaft 38, below the drive shaft bearing 40. An electric motor 44 is connected via a belt 41 to the pulley 42. According to one alternative embodiment the motor may be connected directly to the drive shaft 38.
The crusher 1 is suspended on cushions 45 to dampen vibrations occurring during the crushing action.
The outer and inner crushing shells 12, 18 form between them a crushing chamber 48, to which material that is to be crushed is supplied. The discharge opening of the crushing chamber 48, and thereby the crushing capacity, can be adjusted by means of turning the upper frame portion 4, by means of the threads 8, 10, such that the vertical distance between the shells 12, 18 is adjusted.
When the crusher 1 is in operation the drive shaft 38 is rotated by means of the motor 44. The rotation of the drive shaft 38 causes the unbalance bushing 26 to rotate and as an effect of that rotation the unbalance bushing 26 swings outwards, in the direction of the unbalance weight 30, displacing the unbalance weight 30 further away from the vertical reference axis C, in response to the centrifugal force to which the unbalance weight 30 is exposed. Such displacement of the unbalance weight 30, and of the unbalance bushing 26 to which the unbalance weight 30 is attached, is allowed thanks to the flexibility of the universal joints 34, 36 of the vertical transmission shaft 32, and thanks to the fact that the sleeve shaped unbalance bushing 26 may slide somewhat on the crushing head shaft 24 in the axial direction of the cylindrical bearing 28. The combined rotation and swinging of the unbalance bushing 26 causes an inclination of the crushing head shaft 24, and makes the central axis S of the crushing head 16 and the crushing head shaft 24 gyrate about the vertical reference axis C, such that material is crushed in the crushing chamber 48 between the outer and inner crushing shells 12. Hence, under normal operating conditions, a gyration axis G, about which the crushing head 16 and the crushing head shaft 24 will gyrate, coincides with the vertical reference axis C. In
A control system 46 is configured to control the operation of the crusher 1. The control system 46 is connected to the motor 44, for controlling the power and/or the RPM of the motor 44. A frequency converter 47, for driving the motor 44, is connected between the electric power supply line and the motor 44. The frequency converter 47 is configured to measure the electric power consumed by the motor 44 for rotating the drive shaft 38, and hence acts as a power sensor. The frequency converter 47 is also configured to measure the rotation frequency (RPM) of the motor 44. The readings of the frequency converter 47 are received by the control system 46. Furthermore, the control system 46 is connected to and receives readings from a gyration sensor 50, which senses the location or motion of the gyration sensor reflection disc 27. By way of example, the gyration sensor 50 may comprise three separate sensing elements, which are distributedly mounted in a horiPMontal plane beneath the gyration sensor reflection disc 27, for sensing three vertical distances to the gyration sensor reflection disc 27 in the manner described in detail in EP2116307. Thereby, a complete determination of the tilt of the gyration sensor reflection disc 27, and hence also of the direction of the crushing head central axis S, may be obtained. In the section of
The sensor 50 may be configured to obtain the direction of the central axis S in the manner described above. Alternatively, the sensor 50 may comprise only one single sensing element 50a for sensing the distance Da to one single point on the gyration sensor reflection disc 27. Thereby, the amplitude ADa of the vertical movement of that particular portion on the gyration sensor reflection disc 27 may be obtained, said amplitude ADa of vertical movement representing the projection of the gyration amplitude onto a vertical line passing through said point and the sensing element 50a.
For non-contact sensing of the distances Da, Db to the gyration sensor reflection disc, the gyration sensor 50 may, for example, comprise a radar, an ultrasonic transceiver, and/or an optical transceiver. The gyration sensor 50 may also, or as an alternative, operate by mechanical contact with the gyration sensor reflection disc 27.
In alternative embodiments, the gyration sensor 50 may be configured to sense the absolute or relative location of other parts of the unbalance bushing 26, the crushing head 16, or any components attached thereto.
In yet alternative embodiments, the gyration sensor 50 may be configured to sense the motion of the unbalance bushing 26, the crushing head 16, or any components attached thereto, e.g. by means of an accelerometer or a doppler radar.
Two hatches 7a, 7b in a side wall of the lower frame portion 6 each permit access to at least a respective portion 48a, 48b of the crushing chamber 48 from below. Each hatch 7a-b is associated with a respective lamp 9a, 9b. The lamps 9a, 9b are connected to the control system 46.
In the cross section of
Under such normal operating conditions, material to be crushed 37 is present in the crushing chamber 48. Even though only a relatively thin layer of material to be crushed 37 is illustrated in
When the drive shaft 38 (
During operation, the gyration sensor 50 (
Turning now to
Hence, the control system 46 may detect the presence of tramp material either
based on the change of shape of the gyrating motion of the crushing head central axis S to a non-circular shape, e.g. by comparing the highest value of the angle α with the lowest value of said angle detected during a complete revolution of the gyrating motion of the crushing head 16; or
based on the direction of the gyration axis G deviating from the direction of the vertical reference axis C; or
based on the value of the inclination angle β (
based on the central axis S of the crushing head 16 following a path, as seen in the planar polar coordinates of
based on the gyration amplitude Aα passing a reference amplitude expected for the particular operating conditions; or
based on a combination of any of the above. A detection method combining a plurality of the above indicators gives the most reliable tramp material indication.
An additional, supplementary indicator that a tramp material event has occurred is that the power required for rotating the drive shaft 38 (
Turning to
The constraint introduced by the piece of tramp material 52 also results in the gyration axis G, still defined as the average direction of the central axis S of the crushing head 16, being tilted relative to the vertical reference axis C, and in a reduction of the average value of the apex angle α.
Hence, the control system 46 may detect the presence of tramp material 52 not only based on those tramp material indicators discussed hereinbefore with reference to
based on an increase of the instantaneous or average crushing head inclination i; or
based on a reduction of the average apex angle α; or
based on any combination of those, and any combination with any of those indicators discussed with reference to
d illustrates the tramp material situation of
e illustrates the gyration of the crushing head 16 in the case of multiple small, uncrushable tramp material pieces 52 entering the crushing chamber 48. As the pieces 52 will generally be distributed relatively evenly in the crushing chamber 48 about the crushing head 16, no tilt of the gyration axis will occur; the tramp event will only be detected by measuring the amplitude Aα (illustrated in the cross section by the radial distance R) of the crushing head's 16 gyrating motion, possibly in combination with the detection of a reduction of the crusher's 1 power consumption.
Referring now to
In step 110, a gyration value V, represented by, for example, the direction of the gyration axis G of the crusher 1, is obtained by the control system 46. This may be achieved by, e.g., measuring a number of values of the direction of the crushing head axis S, relative to a reference axis C, over a selected sampling time interval using the sensor 50. The individual spatial vectors obtained in this manner are summed so as to obtain an average direction, which corresponds to the direction of the gyration axis G. Preferably, at least five samples are taken over at least one complete revolution for obtaining a precise direction of the gyration axis G. In a simpler implementation, a rough estimation of the magnitude of the inclination β of the gyration axis G may be obtained by averaging only two values, e.g. the maximum and the minimum values of the tilt i of the central axis S of the crushing head 16 during a time period defined by a sliding time window of a length exceeding at least a period of rotation of the drive shaft 38.
In step 112, the gyration value V, which is in this example represented by the direction of the gyration axis G, is compared with a gyration reference value VR. The gyration reference VR value may, by way of example, be represented by the direction of the vertical reference axis C, but a person skilled in the art may select any reference axis, or any other type of gyration reference value suitable for the particular type of gyration value V.
In step 114, the control system 46 determines, based on the comparison performed in step 112, whether to issue a tramp material warning signal indicating the presence of tramp material 52 in the crusher 1. By way of example, depending on the design of the crusher 1 and the type and siPMe of tramp material 52 that should be detected, the tramp material warning signal may be issued if the angle β (
In the example described above with reference to steps 110-114, the direction of the gyration axis G is compared with the direction of the vertical reference axis C. An alternative is to compare the direction of the gyration axis G with a previously determined direction of the gyration axis G. A fast, sudden change in the direction of the gyration axis G indicates a potential tramp material event. Hence, the method described above may comprise an optional step 116 (dashed), in which the gyration reference value VR assumes the value of a previously obtained gyration value V.
According to an embodiment providing an example of tramp material detection that is based a combination of multiple tramp indications, a good balance between complexity of implementation and reliability of tramp material indication is obtained by a method according to which:
A first tramp material indication is obtained using the method steps 110-112, wherein a first tramp material indication criterion is based on a value |i|n of the average inclination i (
A second tramp material indication criterion is obtained, again using the method steps 110-112, wherein said second tramp material indication criterion is based on the total angle interval, passed by the central axis S of the crushing head in the polar coordinate system of
A third tramp material indication criterion is obtained based on a sampled value PM,n/FM,n of the quotient PM/FM being reduced by more than 25% relative to a previous measurement of PM,n−1/FM,n−1. The quotient PM,n/FM,n represents a power value, and PM,n−1/FM,n−1 represents a power reference value.
If all three criteria are fulfilled, the controller 46 determines that there is a suspected tramp material event, and starts a timer, while repeatedly continuing to obtain V1, V2 and PM,n/FM,n, and comparing them to VR1, VR2 and PM,n−1/FM,n−1, respectively. In case all three tramp material indication criteria remain fulfilled during a predetermined time interval, the controller 46 determines that there is a confirmed tramp event, and issues a tramp material warning signal using the method step 114.
Clearly, instead of comparing the average inclination |i|n with a previously obtained average inclination |i|n−1, the average inclination |i|n may be compared with a predefined value. Similarly, instead of comparing the power value PM,n/FM,n with a previous power value PM,n−1/FM,n−1, also the power value PM,n/FM,n may be compared with a predefined value.
Knowledge of the direction of the gyration axis G relative to a reference axis; the shape of the gyrating motion relative to a reference shape; the angle interval skipped by the central axis S of the crushing head 16 (c.f.
In yet another embodiment of the method of
In said yet another embodiment, in step 110, the amplitude ADa, representing the vertical motion of a portion of the gyration sensor reflection disc 27, may be obtained by measuring a number of values of the distance Da (
In step 112, the gyration value V, represented by the amplitude ADa, is compared with a gyration reference value VR, which may be represented by a reference amplitude AR. By way of example, the reference amplitude AR may be selected, based on the crusher's 1 current load condition, from a table comprising a plurality of reference amplitudes AR1 to ARn, each reference amplitude AR1 to ARn corresponding to a particular load condition of the crusher 1, and representing an expected amplitude at that particular load condition. If the amplitude ADa falls below the reference amplitude AR expected for the current load conditions, a tramp material warning signal is issued.
Referring back again to
Under typical operating conditions, the crusher 1 is filled with crushable material when stopped. The gradual reduction of the excursion of the crushing head 16, as the crusher gradually spins down, allows crushable material to settle in the crushing chamber 48. Therefore, the expected rest position of the central axis S of the crushing head 16, for a cone crusher 1 having crushable material therein, is located relatively near the vertical reference axis C, within the circle P. The gyration reference value VR is thereby represented by the circle P. Hence, any tilt of the central axis S of the crushing head 16 outside the circle P indicates the possibility of tramp material being present in the crushing chamber 48.
Should the crusher be empty when it comes to rest, the unbalance weight 30 (
Referring back again to
Even though only two hatches 7a, 7b are visible in the section of
Also other measures than those used in the method embodiments described in detail above, with reference to
Any of the above methods may be combined with each other, and/or with power monitoring as an additional indicator, thereby increasing the reliability of tramp material detection.
After having detected the presence of tramp material 52 in the crushing chamber 48, corrective measures may be taken. By way of example, the warning signal may be notified to an operator such that the operator may respond to it, and/or the control system 46 may automatically reduce the RPM of and/or power delivered by the drive shaft 38 in order to minimiPMe the risk of damage to the crusher 1. The tramp material warning signal may also be sent to any downstream equipment, such that the downstream equipment may take the required action to automatically remove the tramp material 52 from the flow of crushed material, e.g. by diverting a selected portion of the flow. Furthermore, the tramp material warning signal may be sent to any upstream equipment, so as to reduce or stop the feed of material to be crushed to the crusher 1.
It will be appreciated that numerous variants of the embodiments described above are possible within the scope of the appended claims. For example, the use of a gyration sensor reflection disc 27 has been described above. However, the motion or position of the crushing head 16 may be measured based on the detection of other parts of the crushing head 16, the crushing head shaft 24, or any device connected thereto. Other types of sensors may be used instead of a reflection disc, such as an accelerometer, a camera, or any other suitable means for detecting the position or motion of the crushing head 16.
Above, flexible joints 34, 36 of the universal joint type have been described. However, the crushing head of an inertia cone crusher may be driven via other types of flexible joints.
Hereinbefore, an inertia cone crusher 1 having an unbalance weight 30 attached to the unbalance bushing 26 has been described. In other inertia cone crusher designs, the unbalance weight may have another location than in the crusher 1 described in detail hereinbefore; for example, the unbalance weight may, with appropriate and corresponding modifications to other parts of the crusher, be located on e.g. the crushing head shaft 24 and/or the vertical transmission shaft 32, in which cases those shafts would be unbalance bushings in the meaning of that feature of the appended claims.
Above, it has been described in detail how the distances and angles R, α, i, Aα, and ADa may be used as measures of an amplitude of the gyrating motion of the central axis S of the crushing head 16. As will be appreciated by a person skilled in the art, also other measures indicating the magnitude of the crushing head's 16 gyrating motion may be used as an indication of an amplitude, thereby forming a gyration value based on which tramp material detection may be performed.
It has also been described how different measures of the inclination at rest, the gyration amplitude, the direction of the gyration axis G, the skipped angle φS, and the shape of the gyrating motion of the crushing head 16 may be used as gyration values. Also other measures based on the location or motion of the crushing head, said other measures forming, or enabling the determination of, a gyration value indicative of at least one of an inclination of the gyration axis, a gyrating motion shape, an amplitude of the gyrating motion, and an inclination of the crushing head, may be used for detecting tramp material.
Hereinbefore, it has been described how the crushing power and motor RPM may be obtained by means of a frequency converter. As an alternative, the crusher may be provided with a separate power and/or frequency sensing device, for example a power sensor for measuring only the power consumption, or even with no such sensing means at all.
A gyrating motion in the meaning of this disclosure need not be circular, but may, depending on crusher design and load, be e.g. elliptic, oval, or follow any other type of deformed generatrix due to constraints imposed by e.g. the design of the shape of the crushing chamber 48, or by the presence of any tramp material therein.
Number | Date | Country | Kind |
---|---|---|---|
11170323 | Jun 2011 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP2012/059975 | 5/29/2012 | WO | 00 | 12/16/2013 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2012/171775 | 12/20/2012 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3300149 | Lemardeley et al. | Jan 1967 | A |
3754716 | Webster | Aug 1973 | A |
4272030 | Afanasiev et al. | Jun 1981 | A |
4478373 | Gieschen | Oct 1984 | A |
8496195 | Sjoberg et al. | Jul 2013 | B2 |
20070051837 | Juhlin | Mar 2007 | A1 |
20100288862 | Wark | Nov 2010 | A1 |
20130001337 | Sjoberg et al. | Jan 2013 | A1 |
20140103150 | Belotserkovskiy | Apr 2014 | A1 |
Number | Date | Country | |
---|---|---|---|
20140117127 A1 | May 2014 | US |