WO2017061904A1 - Cone crusher with improved concave fastening - Google Patents

Abstract

The invention is intended for technical processes in the construction and mining and milling industries. The present cone crusher with improved fastening of a concave (2) comprises a housing (1), and a concave (2) and a crushing cone (3) with a crushing chamber therebetween. The housing rests on a foundation (9) via elastic shock absorbers (10). The concave is configured in the form of a cone which transitions at the top into a vertically oriented cylinder. The concave is fastened in an adjustment ring by means of a fastening system. The crushing cone is set in motion by a transmission from an engine. An annular hydraulic fastener in the concave fastening system rests on an adapter ring. At least one mounting groove (29) is provided in the outer surface of the cylindrical part of the concave. At least two identical wedges (24) are inserted into the mounting groove from two opposing sides. The wedges are configured in the form of ring segments with a complex profile and an angular size equal to no greater than 180 degrees. The invention provides for rigid fastening of the concave in the adjustment ring as a result of the surface of the concave and the adjustment ring being in complete contact with one another.

Description

 Cone crusher with improved fixation of external crushing armor

The invention relates to the field of heavy engineering, to crushing crusher equipment, in particular to cone crushers, and can be used in technological processes in the construction and mining and processing industries.

 It is known from the prior art that any cone crusher, for example inertial or eccentric, contains a housing with an outer cone, in other words, armor fixed in the adjusting ring by means of a conical fit. An internal movable cone is placed inside the outer crushing armor, and their facing surfaces form a crushing chamber.

 The internal movable cone is driven by a drive transmission, which in turn is driven by a motor.

 When the inner cone moves, a crushing force is created, which acts on the crushed material in the crushing chamber.

 Common to all types of crushers is the fact that the external crushing armor is under the influence of the tangential component of the crushing force (hereinafter tangential force), which is communicated to it by the moving inner cone. Under the influence of the mentioned force, the external crushing armor strives to turn around its axis.

 In the process, wear occurs on all crushing surfaces, while the load falls to a greater extent on the external crushing armor. Vibration load leads to plastic deformation that occurs in the armor and to deformation of the surface of the adjusting ring, which is designed to fix the armor. Due to this deformation, the landing surfaces of the armor and the adjusting ring lose tight contact with each other and the landing of the armor in the ring is weakened.

 The armor, thus gaining freedom of movement, under the influence of the crushing force of the inner cone beats on the adjusting ring, exposing the latter to the risk of destruction.

The weaker the landing of the outer crushing armor, the less obstacles to the impact of the above tangential force, and the more the armor rotates around its axis. The adjusting ring is one of the most expensive and time consuming when replacing machine parts. In order to prevent the destruction of the adjusting ring is necessary to avoid the phenomena described above.

It is possible to compensate for the weakening of the armor landing by applying efforts to raise the armor up in order to restore the tight fit of the conical surfaces of the armor and the adjusting ring to each other.

 The prior art is an invention aimed at solving the problem, “GYRATORY CRUSHER OUTER CRUSHING SHELL” (“External crushing armor of a gyration crusher”), WO2014019762 (A1), priority data EP20120179085, 02 08 2012.

 The present invention provides several options for attaching an external crushing armor to a cone crusher.

 One embodiment is shown in figures 4 and 5 included in the description. The crusher according to this invention comprises an outer fixed armor and an internal movable crushing cone. The outer fixed armor 200 needs to be rigidly fixed to the conical seat of the adjusting ring 400. It is also necessary to prevent the armor 200 from turning around its axis or the axis of symmetry of the crusher 212.

 In general, the armor 200 is made in the form of a cone, passing in the upper part into a hollow vertically oriented cylinder.

 According to the described embodiment of the invention, the armor 200 is made in such a way that the wall thicknesses 213 of the said cylinder are not equal to each other: on one side, the cylinder wall is made thinning, side B in FIG. 5, compared with the strictly opposite side of the cylinder, side A located 180 ° from side B, respectively. Due to this difference in thicknesses, the axis of symmetry of the inner diameter of the upper cylinder of the armor 200 coincides with the axis of symmetry of the crusher 212 and does not coincide with the axis of symmetry of the outer diameter of the upper cylinder, which is located at some distance to the left of axis 212. Such a technical solution is called eccentricity in the literature.

 A circular groove is made on the outer surface of the armor cylinder. An annular cracker 504 is inserted into this groove at half its width.

 Cracker 504 is supported on a tension ring 401.

 The tension ring 401 around the entire circumference contains threaded holes 505 into which the bolts 404 are inserted.

The bolts 404 abut against the transition ring 403, which is located around the upper conical part of the armor 200. The transition ring 403, in turn, is rigid connected to the adjusting ring 400 surfaces 506 and 507. Adapter ring

403 acts as a support ring for bolts 404.

 The tension ring 401 is fixed against rotation by the ring 402, which is part of the adjusting ring 400. The armor 200 in the lower conical part fits snugly into the adjusting ring 400 along the tapered surfaces 215 and 216, and in the upper cylindrical part into the tension ring 401 along the surfaces 502 and 503 .

At the same time, the tension ring 401 supports the protruding cracker 504. The ring 401, in turn, is fixed with bolts 404, which abut against the adapter ring 403 and are tightened with locknuts.

 Due to the presence of an eccentricity of the outer diameter of the upper cylinder of the armor 200, the axis of symmetry of the entire attachment structure, including tensioner 401 and ring retaining 402, is also shifted away from the symmetry axis 212 of the crusher.

If a torque occurs during operation, the armor 200 is rigidly connected to all the elements of the fastening system and tends to rotate around its axis, however, the presence of an eccentricity prevents this: a conflict is created between the presence of the armor 200 at the same time two axes of symmetry that do not coincide.

 The conditional point located on the surface 502 of the outer diameter of the armor 200 should, due to the eccentricity, during rotation not move along a circular path, but along an ellipsoid. However, this is hindered by the fact that the armor 200 is in close contact without clearance with the tension ring 401, the surface profile of which 503 connected to the armor is a regular circle. A conflict is created between surfaces 502 and 503, which keeps the armor stationary.

 When implemented in practice, significant shortcomings of this solution were revealed.

 The need to thin the armor on the one hand to create eccentricity leads to the fact that a not very hard landing quickly breaks up during crushing, since the effect of vibration affects the more strongly, the thinner the material it affects. Also, in contact with crushed material, the wear of a thinned surface is faster. Thus, the effect of significant plastic deformation occurs in the adjusting ring 400.

All of the above leads to a rapid weakening of the landing of the armor and the appearance of freedom of its movement relative to the adjusting ring, and as a result to the occurrence of the effect of beating the armor. Moreover, the design of the crushing the aggregate does not imply the ability to visually control the occurrence of a beating effect.

 The ability to restore the landing tension in this design is not provided.

 Holding the armor 200 is carried out using bolts 404 supported on the adapter ring 403. However, the installation of such a fastening system involves the need for manual adjustment of at least 12 elements of the locknut at the same time, therefore it is a slow and laborious process. Bolts must be tightened strictly in a certain sequence, with a certain torque, using a special tool, for example, a torque wrench. This operation requires the use of highly qualified employees, takes a significant amount of equipment downtime, and introduces the risk of the influence of the so-called “human factor” on the performance of the unit.

 An additional drawback is the fact that the bolts with locknuts themselves are elements of increased risk, since they take a significant load and are the first to break when the calculated parameters are exceeded due to any reason.

 Thus, the proposed mounting system is unnecessarily complex and not sufficiently reliable.

 Based on the foregoing, an object of the present invention is to provide a crusher armor attachment structure that simultaneously satisfies the following conditions.

 Firstly, the fastening system should fulfill the function of hard fixing the crushing armor in the adjusting ring and ensure full contact of all required surfaces with each other.

 Secondly, the fastening system should provide the ability to compensate for the weakening of the landing, and during the working cycle, without stopping the crusher.

 The most effective will obviously be such a technical solution in which the armor will be subject to the effect of self-tightening, that is, the design of the crusher, in which the external crushing armor tends to rotate around its axis, must be turned into a virtue when the rotation tightens the armor in landing by the principle of a screw.

Thirdly, it is necessary to eliminate such a weak spot of the structure as the use of a large number of pairs of bolt-locknut. Fourth, the armor fastening system should be simple, inexpensive to install and operate, maintainable, and exclude the influence of the “human factor” on the result as much as possible.

 The goals can be achieved by creating a fastener design in which a device operating on the principle of a hydraulic cylinder is used to fix armor in a ring. The prior art hydraulic cylinder is specially upgraded to provide circular support. The weakening of the armor landing should be compensated by the manifestation of the "self-tightening effect" - spontaneous rotation of the armor around its axis, under the influence of the tangential component of the crushing force (hereinafter tangential force), which will restore its full contact with the surface of the adjusting ring. For this, the upper part of the armor and the adapter ring are also being modernized, which becomes a support for the original ring hydraulic fixator.

 According to the present invention, a cone crusher with improved fixation of the external crushing armor contains:

 - a housing supported on a foundation through elastic shock absorbers,

 - external crushing armor made in the form of a cone, passing in the upper part into a vertically oriented cylinder, and fixed in

an adjusting ring by means of a fastening system,

 - an internal cone placed inside the outer crushing armor on a spherical support, forming a crushing chamber between them,

 - the inner cone is driven by a transmission, which, in turn, is driven by a motor.

 The cone crusher has the following main differences:

 - the mounting system of the external crushing armor includes an annular hydraulic retainer supported on a transition ring;

 - on the outer surface of the cylindrical part of the outer crushing armor, at least one annular mounting groove is made, into which at least two identical crackers are inserted, from two opposite sides;

 - crackers are made in the form of a segment of the ring with a complex profile with an angular size of the segment equal to not more than 180 °.

The cone crusher has the following additional differences: - said annular hydraulic fixer consists of a tension ring inside which the annular piston is tightly inserted using gaskets, and the annular cavity formed between the annulus and the piston is filled with oil;

 - on the one hand in the body of the tension ring of the hydraulic fixture there is an oil channel to the oil cavity into which the pressure valve is inserted, and on the back side of the circumference of the tension ring there is a bleed valve;

 - on the upper horizontal plane of the tension ring of the hydraulic fixture, at least two identical screw hoists are made, located at the inner edge opposite each other, and the angular size of each screw hoist is not more than 180 °;

 - each screw lift of the tensioner tension ring is clockwise lifted when viewed from above;

 - at least one locking protrusion is located on the outer circumference of the tension ring, and at least one locking groove corresponding to said protrusion is made on the inside of the adjusting ring.

 The best option is when two locking tabs are located on the outside of the circumference of the tension ring, and two locking grooves are made on the inside of the adjustment ring corresponding to the said tabs.

 Said cracker consists of a cracker body and an internal protrusion of a cracker having a lower height than the body, wherein the height of the cracker body varies from a larger 2 to a smaller hi.

 The lower plane of the body of the said cracker is tilted towards its lower height S, the angle and direction of inclination of the lower plane of the body of the cracker coincides with the angle and direction of inclination of the screw lift on the tension ring of the hydraulic fixer.

 The design of the external crushing armor is made in such a way that an annular mounting groove is made on the cylindrical part of the armor, which represents a horizontal recess of rectangular cross section. The groove has an uneven depth: the minimum depth on one side of the armor circumference, and the maximum depth on the opposite side of the armor circumference.

Also on the outer crushing armor is made an annular fixing groove representing a horizontally located recess of rectangular cross section, located above the installation groove and having unequal depth: the minimum depth from the maximum depth of the installation groove, and the maximum depth from the opposite side.

 On the upper edge of the cylindrical part of the armor, on the outside, a circular groove is made for installing the bottom of the receiving hopper.

 The said crackers are fixed in the mounting grooves of the armor by means of a fixing ring, which is a closed ring with a complex stepped profile of the inner surface, consisting of three circular samples of radii of various sizes.

 The lower inner sample of the retaining ring has the largest of these samples, the radius R4 is equal to the radius of the rusk segment, the radius R3 of the transitional sample is less than R4, and the symmetry axes of the said radii R4 and R3 coincide.

 The upper internal sample of the retaining ring has the smallest of the mentioned samples, the radius R2 is equal to the radius of the fixing groove on the armor, and its axis of symmetry is shifted relative to the symmetry axis of the mentioned radii of the upper R2 and transition R3 of the samples by the eccentricity equal to el + e2.

 The said crackers are fixed in the mounting grooves of the armor by means of a fixing ring so that its lower groove is placed on the installed crackers, and its upper groove is placed on the fixing sample, so that the axis of symmetry of the groove is at a distance of el + e2 from the axis of symmetry of the fixing sample.

 The external crushing armor assembly with rusks and with a retaining ring are oriented relative to the annular hydraulic fixer so that the beginning of each cracker on the side of its maximum height b2 is aligned with the start of the corresponding screw lift on the tension ring of the hydraulic fixator.

 The number of crackers corresponds to the number of screw lifts on the tension ring of the hydraulic fixture, and the angular segment length of said cracker is less than the angular length of the screw lift.

 The direction of the torque transmitted from the engine to the transmission is consistent with the direction of lift of the screw lifts on the tension ring of the hydraulic lock.

The essence of the present invention is illustrated by the following figures. In FIG. 1 shows the implementation of the invention by the example of a cone inertial crusher, presented in cross section.

 In FIG. 2 shows the upper part of the cone inertial crusher in cross section with an enlarged leader of the fastening elements of the armor.

In FIG. 3 shows an external crushing armor with an enlarged leader of the upper part.

 In FIG. 4 presents the design of crackers.

 In FIG. 5 shows the design of the retaining ring.

 In FIG. 6 shows the design of an annular hydraulic lock.

In FIG. 7 and 8 show the upper part of the cone inertial crusher, before and after the manifestation of the self-tightening effect, with enlarged leaders of the elements.

 Figure 9 presents the retaining ring and the upper part of the armor indicating eccentricity.

 The invention can be implemented in any cone crusher, in particular, the figures represent the use of the invention on the example of a cone inertial crusher.

 The housing 1 is mounted on the foundation 9 through elastic shock absorbers 10. The outer crushing armor 2 and the inner crushing cone 3, on which the inner armor 15 is mounted, form a crushing chamber between them. The inner cone 3 is supported on a spherical support 4, between which a sealing system 21 is installed. The outer crushing armor 2 is rigidly fixed in the adjusting ring 18. A receiving hopper 23 is installed on top, into which crushed material is fed. On the shaft 5 of the inner cone 3 is installed the slip sleeve of the unbalance 12 and the unbalance 6. The sleeve is rigidly connected to the transmission clutch 13.

 The transmission clutch 13 is rigidly connected to the “dynamic unit”, including the gear wheel 20, the anti-imbalance 11 and the sliding sleeve 14. The “dynamic unit” is mounted on the fixed axis of rotation 16 through the support disk, with the possibility of rotation around it.

The axis of rotation 16 includes a flange that is rigidly fixed to the bottom of the housing 1 by means of fixing bolts. The axis of rotation and the flange can be made as two different parts, rigidly connected to each other, or as one solid part, acting as a bearing fixed support for the movable “Dynamic node”.

 The “dynamic unit”, in turn, is connected via a gear transmission to the drive shaft assembly 17 through which torque is transmitted from the engine. Oil is supplied to the transmission units through the oil line 7 and the pipe 8.

 The design of the outer crushing armor is shown in FIG. 3.

 Armor 2 is a cone passing in the upper part into a hollow vertically oriented cylinder. The inner surface of the cylinder has an axis of symmetry 44, and a radius R.

 On the outer surface of the cylindrical part of the armor, a groove 29 for installing crackers 24 is filled. The groove 29 is an annular recess of rectangular cross-section, horizontally executed along the entire perimeter of the outer surface of the cylinder, has a bottom radius R1. The depth of the groove is not the same: on the one hand (side M, Fig. 9) the depth of the groove is maximum, strictly on the opposite side (side K) the depth of the groove is minimal. Thus, the groove is eccentric with respect to the axis of symmetry of the armor 44, and the axis of symmetry 45 of the groove 29 is at a distance el from the axis 44.

 Above groove 29, an annular groove 30 is made for installing the retaining ring 43. The groove 30 has a radius R2 and is made of unequal depth: on the one hand (side M), the depth of the groove is minimal and tends to zero, on the other hand (side K), the depth is maximum. Thus, the groove is made with eccentricity with respect to the axis of symmetry of the armor 44, and the axis of symmetry 46 of the groove 30 is in the same plane with the axes 44 and 45 but at a distance e2 from the axis 44.

 In the general case, el is not equal to e2; in the particular case, the values of el and e2 can be equal. Each of the eccentricities el and e2 must be larger than the total size tolerance of the dimensions of the mating parts.

 Above the groove 30, a sample 33 was made for installing the bottom 22 of the receiving hopper 23, the axis of symmetry of which coincides with the axis of symmetry of the armor 44.

 The design of said crackers 24 is shown in FIG. 4, which includes a general view of a cracker, view C is the inside, view D is from the outside, and view E is a top view.

Rusk 24 is a sector of the ring with a complex profile and an angular size β of not more than 180 °. In practice, it is advisable to choose the angular size of sector β in the range of not less than 60 ° and not more than 180 °. The cracker consists of the body of the cracker 35 and the inner protrusion of the cracker 36. The inner protrusion of the cracker 36 has a lower height than the body of the cracker 35.

 The height hi of the cracker body 35 on one side of the sector is less than the height b2 of the cracker body on the other side of the sector. Due to this, the upper plane of the cracker body remains horizontal, and the lower plane of the cracker body 37 is inclined toward a lower height hi. The curvature profile of the inner protrusion 36 must exactly match the curvature relief of the corresponding groove 29 located on the armor 2.

 In the presented embodiment, the change in the height of the rusk from a larger h2 to a smaller L is carried out clockwise when viewed from above (view E) along the lower plane 37 of the rusk body. At the same time, the angle of inclination of the lower plane of the body of the cracker should coincide with the angle of elevation of the screw lift 31.

 FIG. 5 represents the design of the retaining ring 43, designed to prevent the rotation of crackers installed in the grooves of the armor 2.

 The locking ring 43 is a closed ring with an outer radius R, an axis of symmetry 45 and with a complex profile of the inner surface, consisting of three radii of different sizes. The maximum radius R4 has an inner sample 52, the transition sample 51 has a radius R3.

 Sample 50 has the smallest inner radius R2, and its axis 46 is shifted relative to said axis 45 by el + e2, as shown in FIG. 5.

 FIG. 6 shows in detail the design of an annular hydraulic fixer, and FIG. 2 illustrates its location in the unit.

 The design of the hydraulic fixture consists of a tension ring 25, into which the annular piston 27 is tightly inserted, using gaskets 34. The annular cavity 38 between the piston 27 and the ring 25 is filled with oil. The hydraulic lock is supported on the adapter ring 28.

 The adapter ring 28 is mounted on the adjusting ring 18 so that its inclined side surface 42 is in close contact with the inclined surface 41 of the adjusting ring 18.

 On the upper horizontal plane of the tension ring 25, at least two identical screw lifts are performed.

In the described example, the tension ring 25 is made in such a way that on the upper horizontal plane of the ring exactly two identical screw lift 31, located closer to the inner edge, against each other. Each screw lift 31 is made with a clockwise lift when viewed from above. If necessary, the number of screw lifts can be any, and should always correspond to the number of crackers used.

 The angular size γ of each screw lift is most effectively selected in the range of at least 60 ° but not more than 180 °. It is advisable that the angular size γ of the screw lift 31 is larger than the angular size β of the cracker sector 24.

 At least one locking protrusion must be located on the outside of the circumference of the tension ring 25 to prevent the hydraulic lock from turning relative to the adjustment ring 18. At least one receiving groove corresponding to the locking protrusion should be located in the adjustment ring 18.

 In the embodiment of FIG. 6 embodiment, there are two locking protrusions 32 located on two opposite sides and two corresponding receiving grooves on the adjusting ring 18.

 In the body of the tension ring 25 there is an oil channel 47 into which a pressure valve 48 is inserted, through which oil is supplied into the cavity 38. On the reverse side of the circumference of the tension ring 25 is a bleed valve 49, designed to bleed air from the cavity 38.

 The design of the mounting system assembly is shown in FIG. 2.

 An adjusting ring 18 is mounted on the armor 2 until the surfaces 39 and 40 are in contact. An adapter ring 28 is installed in the opening between the armor 2 and the adjusting ring 18 until the surfaces 41 and 42 are in close contact. An annular hydraulic fixer assembly is installed on the adapter ring 28. In this case, the locking protrusions 32 are placed in the corresponding grooves in the upper part of the adjusting ring 18. Crackers 24 are installed on two opposite sides in the groove 29 on the body of the armor 2

When installing parts, the armor 2 and the hydraulic fixer are oriented relative to each other so that the beginning of each cracker 24 on the side of its maximum height h2 strictly coincides with the beginning of the corresponding screw lift 31. Height h3 shows the distance from the upper surface of the tension ring 25 to the upper surface of the neck of the armor 2. The retaining ring 43 is mounted on top of the armor 2 as shown in FIG. 2. When installed, the ring 43 is strictly oriented on the opposite sides of K and M in such a way that the groove 52 fits tightly on the upper and side surfaces of the crackers 24, and the groove 50 falls on the sample 30. In this case, the axis of symmetry 45 of the ring 43 is shifted by a distance el relative to the axis the symmetry of the armor 44 towards the maximum depth of the sample 30 (side K).

 Due to the eccentricity between the groove 29 and the sample 30, the crackers 24 are blocked from turning in the grooves of the armor 2 from above by means of a locking ring 43.

 The hopper 23 is mounted on top, the inner edge of its bottom 22 falls on the corresponding groove 33 in the upper part of the armor 2.

 As a result, each cracker 24 must be fixed between the annular hydraulic retainer, the fixing ring 43.

 The hopper 23 is attached to the adjusting ring 18 by means of a lower flange 26 and bolts 19. The space under the hopper is thus protected from dust.

 The invention works as follows.

 Oil is supplied to the annular hydraulic fixer: a hose from the hydraulic pump is connected to the pressure valve 48, through which oil enters the cavity 38 through the oil channel 47, and excess air is vented through the bleed valve 49 from the cavity 38. After which the pressure valve 48 is closed, the hose is disconnected.

 As a result, a calculated excess oil pressure is created in the cavity 38, under the action of which the tension ring 25 rises and the screw lifts 31 abut against the crackers 24. In this case, the lower surface 37 of the body of the crackers rests on the upper surface of the screw lifts 31.

 In turn, the crackers 24, under the action of the lifting force of the hydraulic clamp, push up the armor 2, as a result of which the inclined planes 39 and 40 are in close contact with each other. In this way, the outer crushing cone 2 is tightly seated in the adjusting ring 18, as illustrated in FIG. 2.

The crusher starts up. In the example under consideration, the engine torque is selected in such a direction that the tendency of the armor to rotate is directed towards the rise of the screw lift 31, that is, clockwise. As it was 8 mentioned above, the direction of lift of the screw lifts on the ring of the hydraulic lock should always coincide with the direction of the tendency of the armor to rotate.

 Plastic deformation of the surface 40 of the adjusting ring 18 leads to loss of tight contact between the surfaces 39 and 40, as a result of which the fit of the armor 2 in the adjusting ring 18 is weakened. Armor 2, thus gaining freedom of movement, under the influence of the crushing force of the inner cone 3 beats against ring 18, exposing the latter to the risk of destruction. The weaker the landing of the armor, the stronger the action of the aforementioned crushing force, and the more the armor 2 rotates around its axis.

 In order to compensate for the weakening of the landing of the armor 2, it is necessary to exert an effort to raise the armor up and achieve restoration of the tight fit of surfaces 39 and 40 to each other.

 When the armor 2 is rotated around its axis, crackers 24, moving together with the armor and the retaining ring 43 as a whole, slide along the screw lifts 31 in the same direction, that is, clockwise when viewed from above. At the same time, the screw lifts themselves, together with the ring 25 of the hydraulic lock remain stationary due to the locking protrusions 32, not allowing the hydraulic lock to rotate around its axis.

 Due to the gradual increase in the height of the screw lifts 31, the crackers 24 gradually moving along the mentioned lifts rise up together with the armor 2, the height p3 also gradually increases.

 The larger the angular distance a passed the armor 2 when turning around its axis, the greater the height h3 it rose relative to the adjusting ring 18, FIG. 8. When the armor 2 is gradually raised upward, the surfaces 39 and 40 also gradually restore an increasingly tight contact around the entire perimeter, which ultimately fixes the armor 2 in the adjusting ring 18 and prevents further rotation.

 The next weakening of the mentioned surfaces, the process repeats: the armor 2 is rotated, the crackers 24 slide along the screw lifts 31 up, raise the armor, the tight contact of the surfaces 39 and 40 is restored, the rotation stops.

The described process is called self-tightening and in the operating mode the crusher does not occur discretely, but constantly. In practice, the working angle of rotation of the armor a is such that at least half of the angular size β of each cracker 24 remains in contact with the corresponding screw lift 31.

 The proposed mounting system has the following advantages.

Universality: the system can be installed on any cone crushers of any size, inertial or eccentric.

 Efficiency: the fastening system uses design features to solve problems arising from these features. The self-tightening effect works independently, without operator intervention, at that moment and to the extent that is required at each stage of the machine.

 Easy maintenance, due to the system design: simple, easily replaceable parts and fixtures are used, which minimizes the influence of the human factor and the use of hand tools.

Claims

Claim

Cone crusher with improved fixation of external crushing armor 1. Cone crusher with improved fixation of external crushing armor comprises a housing supported on a foundation through elastic shock absorbers, an external crushing armor made in the form of a cone, which passes in the upper part into a vertically oriented cylinder and fixed in the adjustment ring using a fastening system, an inner cone placed inside the outer crushing armor on a spherical support, forming a crushing chamber between themselves, inside enny cone is driven by a transmission, which in turn is driven by a motor,

 characterized in that

 external crushing armor mounting system includes a ring

adapter mounted on the adapter ring on the outer surface

at least one mounting groove is made in the cylindrical part of the outer crushing armor, into which at least two identical crackers are inserted from two opposite sides, crackers are made in the form of a ring segment with a complex profile, with an angular segment size of not more than 180 °.

 2. The cone crusher according to claim 1, characterized in that said annular hydraulic fixer consists of a tension ring inside which the annular piston is tightly inserted using gaskets, and the annular cavity formed between the annulus and the piston is filled with oil.

 3. The cone crusher according to claim 2, characterized in that on the one hand in the body of the tension ring of the hydraulic fixture there is an oil channel to the oil cavity into which the pressure valve is inserted, and on the back side of the circumference of the tension ring there is a bleed valve.

 4. The cone crusher according to claim 2, characterized in that at least two identical screw hoists located at the inner edge against each other are made on the upper horizontal plane of the tension ring of the hydraulic clamp, and the angular size of each screw hoist is not more than 180 °.

5. Cone crusher according to claim 2, characterized in that each screw lift of the tension ring of the hydraulic clamp is made to rise clockwise if look from above.

 6. Cone crusher according to claim 2, characterized in that at least one locking protrusion is located on the outside of the circumference of the tension ring, and at least one fixing groove corresponding to said protrusion is made on the inside of the adjusting ring.

 7. Cone crusher according to claim 2, characterized in that on the outer side of the circumference of the tension ring there are two locking protrusions, and on the inner side of the adjusting ring are two locking grooves corresponding to the said protrusions.

 8. The cone crusher according to claim 1, characterized in that said cracker consists of a cracker body and an internal protrusion of a cracker having a lower height than the body; moreover, the height of the cracker body varies from greater h2 to lesser hi.

 9. The cone crusher according to claim 1, characterized in that the lower plane of the body of the said cracker is inclined toward its lower height hi, the angle and direction of inclination of the lower plane of the body of the cracker coincides with the angle and direction of inclination of the screw lift on the tension ring of the hydraulic fixer.

 10. The cone crusher according to claim 1, characterized in that on the outer surface of the cylindrical part of the external crushing armor an annular mounting groove is made, representing a horizontally located recess of rectangular cross section and having an uneven depth: the minimum depth on one side of the armor circumference and the maximum depth on the opposite side the circumference of the armor.

 11. The cone crusher according to claim 1, characterized in that on the outer surface of the cylindrical part of the external crushing armor a circular fixing groove is made, representing a horizontal recess of rectangular cross section located above the installation groove and having an uneven depth: the minimum depth from the maximum depth of the installation groove , and maximum depth on the opposite side.

 12. The cone crusher according to claim 1, characterized in that on the upper edge of the cylindrical part of the external crushing armor, from the outside, a circular groove is made for installing the bottom of the receiving hopper.

13. Cone crusher according to claim 1, characterized in that the said crackers are fixed in the installation grooves of the armor by means of a locking ring, representing a closed ring with a complex stepped profile of the inner surface, consisting of three circular samples having radii of various sizes.

 14. The cone crusher according to claim 1, characterized in that the lower inner sample of the retaining ring has the largest of these samples, the radius R4, equal to the radius of the rusk segment, the radius R3 of the transitional sample is smaller than the radius R4, and the symmetry axes of the said radii R4 and R3 coincide.

 15. The cone crusher according to claim 1, characterized in that the upper inner sample of the retaining ring has the smallest of these samples radius R2 equal to the radius of the fixing groove on the armor, and its axis of symmetry is shifted relative to the axis of symmetry of the mentioned radii of the upper R2 and transition R3 samples by the amount of eccentricity equal to el + e2.

 16. The cone crusher according to claim 1, characterized in that the said crackers are fixed in the mounting grooves of the armor by means of a fixing ring so that its lower groove is placed on the installed crackers, and its upper groove is placed on the fixing sample so that the axis of symmetry of the groove was at a distance el + e2 from the axis of symmetry of the fixing sample.

 17. The cone crusher according to claim 1, characterized in that the outer crushing armor assembly with the rusks and with the retaining ring are oriented relative to the annular hydraulic fixer so that the beginning of each cracker on the side of its maximum height b2 is aligned with the beginning of the corresponding screw lift on the tension hydraulic lock ring.

 18. The cone crusher according to claim 1, characterized in that the number of crackers corresponds to the number of screw lifts on the tension ring of the hydraulic fixture, and the angular length of the segment of each said cracker is less than the angular length of the corresponding screw lift.

 19. The cone crusher according to claim 1, characterized in that the direction of the torque transmitted from the engine to the transmission is consistent with the direction of lift of the screw hoists on the tension ring of the hydraulic fixer.