JP2559316B2 - Spindle crusher spindle assembly structure - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a main shaft assembly structure of a rotary crusher, and more particularly to a main shaft assembly structure of a rotary crusher in which a thread portion of a bearing journal is omitted.

[0002]

2. Description of the Related Art A mantle of a rotary type crusher is for crushing an object to be crushed in cooperation with a cone cave, and has been conventionally constructed as shown in FIG. 3 by taking a gyre re-crusher as an example.

In the figure, reference numeral 1 denotes an upper frame in the shape of a truncated inverted conical tube. The upper frame 1 comprises a plurality of (two in FIG. 3) frames 1a and 1b arranged in series, and a frame (not shown). )
It is connected to the upper part of the lower frame 2 placed on the.

A sleeve 4 having an eccentric shaft hole 3 penetrating in the vertical direction is rotatably fitted into the boss portion 2a of the lower frame 2, and the eccentric shaft hole 3 has an axial center of both frames 1, 2. The lower end of the main shaft 5 arranged in the section is inserted.
The lower end of the main shaft 5 is supported by a lower bearing 6 such as a thrust bearing, and the lower bearing 6 supports the boss portion 2 of the lower frame 2.
It is supported by a piston 8 of a hydraulic cylinder 7 for lifting and lowering a spindle connected to the lower end of a. The upper end of the main shaft 5 is supported by an upper bearing 9 such as a radial spherical bearing.
Are supported by a spider 11 which is integrated with a rim 10 attached to the upper end of the upper frame 1.

A mandrel 12 in the shape of a truncated cone is integrally provided on the main shaft 5 so as to face the inner peripheral surface of the upper frame 1, and the truncated cone 12 is made of high manganese cast steel. A body-shaped mantle 13 is fitted.
On the other hand, on the inner peripheral surface of the upper frame 1, the cone cave 14
In order to form the above, a plurality of inverted trapezoidal plate-shaped corn cave segments 14a made of high-manganese cast steel are mounted in a zigzag manner in a multi-row, multi-stage manner with a proper clearance between them. A crushing chamber 16 having a wedge-shaped cross section is formed between the cone cave 14 and the mantle 13.

A driven bevel gear 17 is attached to the lower end of the sleeve 4, and a driven bevel gear 19 attached to the inner end of a horizontal rotary shaft 18 is meshed with the driven bevel gear 17. The horizontal rotary shaft 18 is supported by a casing 20 attached to the lower frame 2 via a bearing 21, and an outer end portion of the horizontal rotary shaft 18 is interlocked with a motor (both not shown) via a belt. A pulley 22 is attached.

The main shaft 5 is integrated with the bearing journal 23 having a threaded portion 39 at the top, and the threaded portion 39
The mantle 13 is fitted on the mantle door 12 by self-tightening of the head nut 28 'that is fastened to the mantle 13 (for example,
Japanese Patent Publication No. 3-5854).

Further, as a spindle assembly structure in which the threaded portion of the bearing journal is omitted, a threaded portion is provided on the outer lower portion of the journal sleeve of the bearing journal to be fastened to the head nut, and the head nut is self-tightened to secure the main shaft surface. It is known that the mantle is fitted into the. In this structure, the journal sleeve is fixed to the bearing journal by shrink fitting, and a clearance is formed between the inner surface near the threaded portion and the bearing journal, so that the screw is precisely generated and the stress at the threaded portion is increased. In order to avoid a decrease in strength due to concentration, the head nut is prevented from transmitting the tightening action to the main shaft by direct contact (for example, Japanese Patent Publication No. 1-17743).

[0009]

In the spindle assembly structure in which the bearing journal is provided with the threaded portion, the spindle itself is used when an abnormal state occurs due to the operation of the crusher and the threaded portion is damaged. There is a risk that it will be impossible, and it is not good.
Further, in the main shaft where a complicated stress acts under severe usage conditions, it is inevitable that the thread portion of the bearing journal has a special consideration for strength reduction.

Further, in the spindle assembly structure in which the bearing journal has no threaded portion, it is effective in that the spindle itself can be prevented from becoming unusable if the threaded portion is damaged, but the tightening action of the head nut is Since it is floated in the radial direction with respect to the axis of the spindle, it is not preferable because the mantle may not be fitted securely on the surface of the spindle under a sufficient tightening force.

The present invention has been made to solve the above-mentioned problems of the prior art, and it is possible to avoid forming a clearance between the lower portion of the journal sleeve and the bearing journal, and to prevent the head nut. It is intended to provide a spindle assembly structure of a rotary crusher in which the self-tightening action of the directly acts on the spindle and the mantle through the annular connector, and the mantle can be securely fitted to the surface of the spindle. To do.

[0012]

In order to achieve the above object, in the present invention, a bearing journal having a smooth surface is provided on the top of a main shaft fitted with a mantle, and a journal sleeve is provided outside the bearing journal. The ring-shaped connector that is attached and contacts the continuous part of the main shaft and the bearing journal is fitted to the lower end of the bearing journal at the inner circumference, and the threaded part is provided on the outer circumference to self-tighten with the head nut. The bottom of the partial nut presses the top of the mantle, and the inner top of the annular connector is provided with engaging means for engaging the lower end of the journal sleeve.

[0013]

In this way, even if the journal sleeve or the screw part is damaged during the operation of the rotary crusher, the main shaft can be protected from damage, and the head nut itself can be protected by the annular connector. Due to the tightening action, the tightening force directly acts on the main shaft and the mantle, so that the mantle can be securely fitted on the main shaft and the mantle. Moreover, the engagement means can be used to effectively prevent the journal sleeve from rotating during operation.

[0014]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a cross-sectional view of a spindle assembly structure of a rotary crusher showing an embodiment of the present invention, and FIG. 2 is a cross-sectional view of a main part of the engaging means, showing members common to those shown in FIG. Are given the same reference numerals.

In FIGS. 1 and 2, a mantle 13 is fitted on the mantle cover 12 of the main shaft 5, and a bearing journal 23 having a smooth surface is provided on the top of the main shaft 5 in an integrated structure with the main shaft 5. are doing. A journal sleeve 24 is attached to the outside of the bearing journal 23 by a tight fit or the like. Further, the journal sleeve 24 is attached to the upper ends of the bearing journal 23 and the journal sleeve 24 by a top plate 25 using bolt means 26 or the like so as to prevent rotation. The journal sleeve 24 is adapted to fit in a bearing device (not shown).

A continuous portion 3 between the main shaft 5 and the bearing journal 23
On the upper part of 8, a ring-shaped connector 27 is mounted between the head nuts 28 at the lower end of the journal sleeve 24 in the axial direction of the main shaft 5. The annular connector 27 is fitted in close contact with the lower end of the bearing journal 23 on the inner circumference, and the threaded portion 33 is provided on the outer circumference and fitted with the threaded portion of the head nut 28. Further, an engagement means 32 for engaging with the lower end of the journal sleeve 24 is provided on the inner top portion 27a of the annular connector 27.

As the engaging means 32, for example, a plurality of convex tooth portions 30 are provided on the outer circumference at the lower end portion of the journal sleeve 24.
And a plurality of concave tooth portions 31 are provided on the inner circumference of the inner top portion 27a of the annular connector 27, and the convex tooth portion 30 and the concave tooth portion 31 are engaged with each other at the inner top portion 27a. The bottom portion of the head nut 28 presses the top portion of the mantle 13.

As described above, the bearing journal 23 and the journal sleeve 24 are attached to each other by a fitting fit such that the convex tooth portion 30 of the journal sleeve 24 and the concave tooth portion 31 of the annular connector 27 are engaged, and , The top plate 25 is attached by using the bolt means 26, the mantle 13 is fitted on the mantle door 12, and the head nut 28 is securely tightened, and then the pin 37 is driven to complete the tightening.

The self-tightening action of the head nut 28 will be described assuming that the mantle assembly is rotated to the right during operation of the rotary crusher. The ring-shaped connector 27 and the head nut 28 are formed by a right-hand thread, and during load operation, the mantle 13 receives a force that rotates to the right with respect to the mantle door 12 as viewed from above as a crushing reaction force. The head nut 28 is also rotated in the same direction to the right when viewed from above via the pin 37, and the downward tightening force of the head nut 28 is self-tightening the main shaft 5 via the annular connector 27. It directly acts on the mantle door 12 and the mantle 13, so that the mantle 13 can be securely fitted onto the mantle door 12. On the other hand, in the annular connector 27 screwed into the head nut 28, upward pushing force and rotational torque are induced by the right rotation, but the inner top 27a of the annular connector 27 is engaged. The upward pushing force of the journal sleeve 24 via the means 32 causes the top plate 25,
Since it is restrained by the bolt means 26, the upward movement is prevented and the rotation movement of the journal sleeve 24 is also restrained effectively by the engagement means 32, and the bottom surface of the annular connector 27 is Continuous part 38
Since it is in contact with the main shaft 5, the mantle 13 is fitted on the main shaft 5 and the mantle cover 12 while avoiding the formation of a clearance between the inner surface near the screw and the bearing journal as in the conventional case. The maximum tightening force can be applied.

In this way, the main shaft assembly structure in which the screw part is omitted in the bearing journal is formed, and even if the journal sleeve or the screw part is damaged during load operation of the rotary crusher, the main shaft is protected from damage. By the self-tightening action of the head nut through the annular connector, the tightening force directly acts on the main shaft and the mantle, so that the mantle can be securely fitted on the main shaft and the mantle. Moreover, the engagement means can be used to effectively prevent the journal sleeve from rotating during load operation.

Further, since the threaded portion of the annular connector is machined as a single component, accurate screw creation is possible and not only the machining by a large machining machine is omitted, but also
It is possible to avoid a decrease in the strength of the spindle. Furthermore, it is possible to avoid the formation of the play space as described above, and it is possible to maximize the tightening force for fitting the mantle cover onto the main shaft and the mantle cover.

FIG. 2 shows an embodiment of the engaging means.

In FIG. 2 (a), the details of the basic mode of FIG. 1 are shown, and the convex tooth portion 30 is provided on the upper surface 34 of the annular connector 27a.
a, the tip of the convex tooth portion 30a 'is located on the lower surface 35 of the sleeve ring 24a, and the bottom of the concave tooth portion 31a' of the sleeve ring 24a is located on the upper surface 34.
The bottoms of the concave teeth 31a of the annular connector 27a are located on the lower surface 35 and are engaged with each other.

In FIG. 2B, the bottom of the concave tooth portion 31b is located on the upper surface 34 of the annular connector 27b, the tip of the convex tooth portion 30b 'is located on the lower surface 35 of the sleeve ring 24b, and The tip of the convex tooth portion 30b of the annular connector 27b is positioned at the upper portion, and the bottom portion of the concave tooth portion 31b 'of the sleeve ring 24b is positioned so as to be engaged with each other.

In FIG. 2C, the upper surface 34 of the annular connector 27c and the lower surface 35 of the sleeve ring 24c are aligned with each other, and a plurality of pins 36 are circumferentially arranged in the respective thickness directions. , Are mutually engaged.

In FIG. 2 (d), an external thread 39 is provided above the upper surface 34 of the annular connector 27d and is engaged with each other by an internal thread 39 'provided near the lower surface 35 of the sleeve ring 24d. .

[0027]

As described above, according to the present invention,
Even if the journal sleeve or screw part is damaged during load operation of the rotary crusher, the spindle can be protected from damage, and the tightening force is increased by the self-tightening action of the head nut via the annular connector. By directly acting on the main shaft and the mantle, the mantle can be securely fitted on the main shaft and the mantle. Moreover, the engagement means can be used to effectively prevent the journal sleeve from rotating during load operation. In addition, since the bearing journal does not have a threaded portion as in the conventional case, it is possible to avoid a decrease in the strength of the main spindle, and it is also possible to avoid the formation of a gap between the journal sleeve and the bearing journal, which results in A great effect is exerted, such as the maximum tightening force for fitting the mantle cover.

[Brief description of drawings]

FIG. 1 is a sectional view of a spindle assembly structure of a rotary crusher showing an embodiment of the present invention.

FIG. 2 is a sectional view of an essential part of the engaging means.

FIG. 3 is an overall configuration diagram of a spindle assembly structure of a conventional rotary crusher.

[Explanation of symbols]

 5 Spindle 13 Mantle 23 Bearing Journal 24 Journal Sleeve 27 Annular Connector 28 Head Nut 32 Engaging Means 33 Threaded Part 38 Continuous Part

 ─────────────────────────────────────────────────── --Continued front page (56) References JP-A-57-87851 (JP, A) JP-B-47-709 (JP, B1)

Claims (1)

(57) [Claims] 1. An annular connector having a bearing journal having a smooth surface on the top of a main shaft fitted with a mantle, and a journal sleeve attached to the outside of the bearing journal so as to abut a continuous portion between the main shaft and the bearing journal. Is fitted with the lower end of the bearing journal on the inner circumference, and is self-tightly fastened to the head nut by providing a threaded portion on the outer circumference.The bottom of the head nut presses the top of the mantle, and the annular connector A spindle assembly structure for a rotary crusher, characterized in that engaging means for engaging with a lower end portion of a journal sleeve is provided on an inner top portion of the shaft.