JP6509556B2 - Jaw crusher - Google Patents

Description

  The present invention relates to a jaw crusher for compressing and crushing an object to be treated, and more particularly to a jaw crusher capable of easily adjusting the stroke of the lower end portion of a movable tooth.

  Conventionally, as shown in FIG. 15, a jaw crusher is known as a primary treatment facility for compressing and crushing an object to be treated such as rock, ore, concrete waste material, asphalt waste material and the like.

  The jaw crusher 101 shown in FIG. 15 includes a frame body 102, fixed teeth 103 provided at the front of the frame body 102, a swing jaw 104 having an upper portion eccentrically rotatably supported by the frame body 102, and swing jaws. And a movable tooth 106 which is provided at 104 and forms a crushing chamber 105 for crushing an object to be processed with the fixed tooth 103. Among them, the frame body 102 has a pair of side frames 107, and the fixed teeth 103 and the movable teeth 106 are provided between the pair of side frames 107.

  The side frame 107 is provided with an eccentric shaft 108, and a pulley 109 is attached to the axial end of the eccentric shaft 108. The rotational driving force of an electric motor (not shown) is transmitted to the pulley 109 via a belt. Further, an upper portion of the swing jaw 104 is rotatably supported by the eccentric shaft 108.

  A tension rod 110 is connected to the lower portion of the swing jaw 104, and the tension rod 110 is biased rearward by a spring 111.

  The rear of each side frame 107 is connected by a rear frame 112, and a toggle block 113 is attached to the rear frame 112. A first adjusting plate 114 is interposed between the rear frame 112 and the toggle block 113, and the outlet gap (maximum gap between the lower end of the fixed tooth 103 and the lower end of the movable tooth 106) in the crushing chamber 105 can be adjusted. It has become. The toggle block 113 is attached to the rear frame 112 via the first bolt 115 together with the first adjusting plate 114. The first bolt 115 extends in the horizontal direction, and is attached to the rear frame 112 so as to pull the toggle block 113 rearward.

  Further, a guide bracket 116 is fixed to the inner surface of each side frame 107, and both ends of the toggle block 113 are attached to the guide bracket 116. A second adjusting plate 117 is interposed between the guide bracket 116 and the toggle block 113 so that the stroke of the lower end portion of the movable tooth 106 can be adjusted. The toggle block 113 is attached to the guide bracket 116 via the second bolt 118 together with the second adjusting plate 117. The second bolt 118 extends in the vertical direction and is attached to the guide bracket 116 so as to lift the toggle block 113.

  A toggle plate 119 is interposed between the swing jaw 104 and the toggle block 113 to provide the swing jaw 104 with a rocking motion relative to the fixed tooth 103. The swing jaw 104 is provided with a front toggle seat 120 with which the front end of the toggle plate 119 slidably contacts, and the rear end of the toggle plate 119 slidably contacts the toggle block 113 A rear toggle seat 121 is provided.

  With such a configuration, when the electric motor is driven, the upper portion of the swing jaw 104 is eccentrically rotated, whereby the lower portion of the swing jaw 104 swings relative to the fixed tooth 103 so as to draw an elliptical shape. When an object to be treated as a raw material is introduced into the crushing chamber 105, the object to be treated is sequentially compressed and crushed, and is discharged from the outlet of the crushing chamber 105 as a crushed material.

JP 10-249224 A

  By the way, the hardness differs depending on the type of the object to be treated. For this reason, in order to prevent damage to the jaw crusher 101, it is preferable to set an appropriate stroke according to the hardness. For example, in the case of breaking a hard object to be treated with a large stroke, the frame body 102 may be deformed. Moreover, even if it is the same kind of processing object, the property may be different, and it may be difficult to set an appropriate stroke unless crushing processing is actually performed. Based on the above, in the jaw crusher 101 shown in FIG. 15, the stroke of the lower end portion of the movable tooth 106 is adjustable.

  When adjusting the stroke of the lower end portion of the movable tooth, first, the first bolt 115 is removed to release the toggle block 113 from restraint on the rear frame 112. As a result, the toggle block 113 is suspended by the second bolt 118. Subsequently, the second bolt 118 is loosened to form a gap between the toggle block 113 and the guide bracket 116. Next, the second adjusting plate 117 is inserted and removed, and the number or thickness of the second adjusting plate 117 is adjusted. Subsequently, the second bolt 118 is tightened to fix the toggle block 113 to the guide bracket 116. Thereafter, the first bolt 115 is tightened, the toggle block 113 is fixed to the rear frame 112, and the stroke adjustment operation is completed.

  However, the first bolt 115 and the second bolt 118 are relatively large sized bolts, such as M48, to secure the heavy toggle block 113 to the rear frame 112 or the guide bracket 116. In particular, the second bolt 118 may be large because it is required to have a strength that can withstand the weight of the heavy toggle block 113. In general, the work of loosening and tightening such a large size bolt is a labor-intensive work, and the aging of general field workers of the jaw crusher 101 is also advancing in these days. It is difficult to handle the bolt and adjust the stroke.

  The present invention has been made in consideration of these points, and it is an object of the present invention to provide a jaw crusher capable of easily adjusting the stroke of the lower end portion of the movable tooth.

  The present invention provides, as a first solution, a swing jaw having a frame body, fixed teeth provided on the frame body, an upper portion eccentrically rotatably supported by the frame body, and the swing jaw A movable tooth forming a crushing chamber between the fixed tooth, a biasing part urging the lower part of the swing jaw to the opposite side to the fixed tooth side, and the frame body provided with a space apart from each other A pair of guide structures, a block interposed between the pair of guide structures, and a block which can be pulled out from the storage area between the pair of guide structures, and between the swing jaw and the block And a toggle plate, which intervenes and imparts a swinging motion to the fixed jaw with respect to the fixed tooth, wherein the block body is viewed in the direction of the eccentric rotation axis of the swing jaw. The concave plate has a concave surface formed in a shape in contact with the end of the toggle plate on the side of the block body, and when the block body is viewed from the side of the toggle plate, the concave plane The center line provides a jaw crusher characterized by being eccentric to the center line of the accommodation area.

  In the jaw crusher according to the first solution described above, the guide structure extends obliquely downward toward the swing jaw, and the end of the guide structure on the swing jaw side is The locking member for locking the block body may be removably attached by a locking bolt.

  Further, in the jaw crusher according to the first solution described above, the guide structure has a guide member for guiding the block body, and the block body is attached to each of the guide structures via the guide member. The sliding member may be slidable, and the locking member may be removably attached to the guide member.

  Further, according to the present invention, as a second solution, a swing jaw having a frame body, fixed teeth provided on the frame body, an upper portion eccentrically rotatably supported by the frame body, and the swing jaw Provided on the frame body, a movable tooth that is provided and that forms a crushing chamber with the fixed tooth, a biasing unit that biases the lower part of the swing jaw to the opposite side to the fixed tooth side, A first guide structure and a second guide structure which are separated from each other, a block body interposed between the first guide structure and the second guide structure, and a space between the swing jaw and the block body And a liner structure detachably attached to the block body, the toggle body including: A concave surface formed in a concave shape when viewed in the direction of the eccentric rotation axis of the swing jaw, with which the end on the block body side of the toggle plate abuts, and the liner structure includes the block A jaw crusher characterized by comprising a liner interposed at least one of between a body and the first guide structure and between the block and the second guide structure. Do.

  In the jaw crusher according to the second solution described above, the liner structure further includes a mounting portion connected to the liner and removably mounted on the block by a mounting bolt. You may

  In the jaw crusher according to the second solution described above, the first guide structure is disposed below the block body, and the liner structure is removed from the first guide structure. A support member for supporting the block body may be provided.

  According to the present invention, the stroke of the lower end portion of the movable tooth can be easily adjusted.

FIG. 1 is a side sectional view showing a jaw crusher according to a first embodiment of the present invention. FIG. 2 is an enlarged view of the block body of FIG. FIG. 3 is a view showing the block body of FIG. 1 and is a view on arrow A of FIG. FIG. 4 is a view showing the block body of FIG. 3 upside down. FIG. 5 is a view showing a cross section taken along the line B-B of FIG. FIG. 6 is a view showing a cross section taken along the line B-B in FIG. FIG. 7 is a view for explaining the stroke of the lower end portion of the movable tooth. FIG. 8 is a view showing a toggle block and a liner structure in the second embodiment of the present invention, and a view corresponding to a view on arrow A of FIG. FIG. 9 is a top view of FIG. FIG. 10 is a side view of FIG. FIG. 11 is a view showing another example of the liner structure of FIG. FIG. 12 is a side view of FIG. FIG. 13 is a view showing another example of the liner structure of FIG. FIG. 14 is a side view of FIG. FIG. 15 is a side sectional view showing a conventional jaw crusher.

  A jaw crusher according to an embodiment of the present invention will be described below with reference to the drawings.

First Embodiment
A jaw crusher according to a first embodiment of the present invention will be described with reference to FIGS. 1 to 7. Here, the jaw crusher is suitably used as a primary treatment facility for compressing and crushing an object to be treated such as rock, ore, concrete waste material, asphalt waste material and the like.

  As shown in FIG. 1, the jaw crusher 1 is eccentrically rotatably supported by the frame body 2, fixed teeth 3 provided on the front portion (left side in FIG. 1) of the frame body 2, and the frame body 2. A swing jaw 4 having an upper portion, and movable teeth 6 provided on the swing jaw 4 and forming a crushing chamber 5 in which the object S is crushed between the fixed teeth 3 are provided. More specifically, the frame body 2 has a pair of side frames 7, and the fixed teeth 3 and the movable teeth 6 are provided between the pair of side frames 7. The movable tooth 6 is disposed rearward of the fixed tooth 3, and the crushing chamber 5 is formed by the fixed tooth 3, the movable tooth 6 and the pair of side frames 7. The fixed teeth 3 and the movable teeth 6 are formed in a wave shape when viewed from above, and apply a compressive force to the object S from the peaks (tops) thereof.

  An eccentric shaft 8 is rotatably provided at an upper portion of the side frame 7. The eccentric shaft 8 extends through both side frames 7 to the outside of each side frame 7, and a pulley 9 is attached to an axial end formed on the outside of each side frame 7. The rotational driving force of an electric motor (not shown) is transmitted to the pulley 9 via a belt.

  The upper portion of the above-mentioned swing jaw 4 is rotatably supported by the eccentric shaft 8. The rotation axis of a portion of the eccentric shaft 8 supporting the swing jaw 4 is eccentric to the rotation axis of the pulley 9 (shown by the center of rotation O in FIG. 1). As a result, when the pulley 9 rotates, the swing jaw 4 rotates the rotation center O of the pulley 9 so that the upper part of the swing jaw 4 draws a circle whose radius is the eccentricity around the rotation center O of the pulley 9. It is designed to rotate eccentrically as the center. A line perpendicular to the paper surface of FIG. 1 through the center O is the eccentric rotation axis of the swing jaw 4.

  The lower portion of the swing jaw 4 is biased rearward (opposite to the side of the fixed tooth 3) by a spring 10 (biasing portion). More specifically, the tension rod 11 is connected to the lower portion of the swing jaw 4, and the spring 10 is a frame spring receiver 12 fixed to the side frame 7 and a rod spring receiver fixed to the tension rod 11. It is interposed between the part 13. Thus, the tension rod 11 is biased rearward by the spring 10 to apply a rearward tensile force to the lower portion of the swing jaw 4. The biasing force of the spring 10 is adjustable by the cylinder 14 fixed to the rod spring receiving portion 13.

  By the way, on the inner surface of each side frame 7, a pair of guide structures (a first guide structure 21 and a second guide structure 22) separated from each other are provided. Among these, the first guide structure 21 is disposed below the block 25 described later, and the second guide structure 22 is disposed above the block 25. An accommodation area 23 in which the block 25 is accommodated is formed between the first guide structure 21 and the second guide structure 22.

  Each guide structure 21, 22 extends obliquely downward toward the front (the side of the swing jaw 4). The front end of the storage area 23 formed between the two guide structures 21, 22 is open, and the rear end of the storage area 23 is closed by the rear frame 24. The rear frame 24 is fixed to the rear ends of the guide structures 21 and 22 and the side frame 7. The guide structures 21 and 22 and the rear frame 24 extend from the inner surface of one side frame 7 to the inner surface of the other side frame 7 and are fixed to the pair of side frames 7.

  A block 25 is interposed between the first guide structure 21 and the second guide structure 22. The block 25 is accommodated in the accommodation area 23 so as to be able to be drawn out, slidable with respect to each of the guide structures 21 and 22, and guided along the advancing / retracting direction P shown in FIG. It is possible to advance and retract while sliding against 22.

  As shown in FIGS. 1 and 2, each of the guide structures 21 and 22 is fixed to the guide frame 26 fixed to the side frame 7 and to the inner surface (the surface on the side of the block 25) of the guide frame 26 And a guide member 27 for guiding the body 25. The block body 25 can slide on the guide structures 21 and 22 via the guide member 27. The guide member 27 is, as shown in FIG. 3, at both ends of the block 25 and above when the block 25 is viewed from the side of the toggle plate 40 (when viewed in the direction of arrow A in FIG. 1). And are located below. That is, each guide structure 21, 22 has two guide members 27, and one block body 25 is guided by four guide members 27. Further, as shown in FIGS. 1 and 2, each guide member 27 extends from the front end to the rear end of the housing area 23, and both ends of the block 25 correspond to each other as shown in FIG. A guided portion 28 for receiving the guide member 27 is formed. The corresponding guide members 27 abut on the respective guided portions 28 so that the block body 25 can slide while being guided by the guide members 27. The facing area of the guide member 27 to the block 25 is smaller than the facing area of the guide structures 21 and 22 to the block 25, and the contact area between the guide member 27 and the block 25 is reduced. Are slidable relative to the guide member 27.

  As shown in FIG. 2 and FIG. 3, the stopper 30 (locking member) for locking the block 25 is a stopper bolt 31 (locking member) at the front end of the guide structure 21, 22 (end on the swing jaw 4 side). It is removably attached by a locking bolt). In the present embodiment, the stopper 30 is removably attached to the front end portion of the above-described guide member 27 by the stopper bolt 31. In the example shown in FIG. 3, the guide member 27 is formed in a rectangular shape when viewed from the front, the stopper 30 is formed in a circular shape, and the stopper 30 has a diameter that protrudes from the guide member 27 ing. As a result, the block 25 located at the front end of the storage area 23 is locked by the stopper 30 to prevent the block 25 from being pulled out of the storage area 23. On the other hand, removal of the stopper 30 enables the block body 25 to be pulled out.

  The stopper 30 is for preventing the block body 25 located at the front end of the accommodation area 23 from being pulled out from the accommodation area 23, as described above. From this, the stopper bolt 31 should just have the strength which can support the block body 25 located in the front end of the accommodation area 23 in the position. Further, the weight of the block 25 positioned at the front end of the housing area 23 is received by the lower first guide structure 21 and the stoppers 30. As a result, much of the weight of the block 25 can be received by the first guide structure 21, and the load applied to the stopper 30 can be reduced. Therefore, the strength required for the stopper 30 and the stopper bolt 31 can be reduced, and the size of the stopper bolt 31 can be reduced.

  As shown in FIGS. 1 and 2, a toggle plate 40 is interposed between the swing jaw 4 and the block 25. The toggle plate 40 is for applying a swinging motion to the fixed teeth 3 to the swing jaw 4. The front end portion and the rear end portion of the toggle plate 40 are formed in a curved shape, and the front end portion of the toggle plate 40 performs sliding movement with respect to the swing jaw 4 and the rear end portion of the toggle plate 40 It is designed to carry out a sliding movement.

  More specifically, a front toggle seat 41 is provided at the rear of the swing jaw 4. The front toggle sheet 41 has a front concave surface 42 with which the front end of the toggle plate 40 abuts, as shown in FIG. The front concave surface 42 is concave and curved when viewed in the direction of the eccentric rotation axis of the swing jaw 4, and the front concave portion of the toggle plate 40 abuts on the front concave surface 42 while the front end of the toggle plate 40 abuts. A sliding movement is provided along the surface 42.

  As shown in FIGS. 1 and 2, the block 25 includes a toggle block 43 and a rear toggle sheet 44 provided at the front of the toggle block 43. Among them, as shown in FIG. 2, the rear toggle sheet 44 has a rear concave surface 45 (concave surface) with which the rear end portion of the toggle plate 40 abuts. The rear concave surface 45 is formed in a concave and curved shape when viewed in the direction of the eccentric rotation axis of the swing jaw 4 and the rear concave portion of the toggle plate 40 abuts on the rear concave surface 45 It is designed to perform a sliding movement along the way.

  As shown in FIGS. 3 and 4, the center line C1 of the rear concave surface 45 is offset with respect to the center line C2 of the housing area 23 in the vertical direction when the block 25 is viewed from the toggle plate 40 side. I have a heart. In the example shown in FIG. 3, the center line C <b> 1 of the rear concave surface 45 is eccentric upward with respect to the center line C <b> 2 of the accommodation area 23. The block 25 can be reversed in the vertical direction by pulling out from the housing area 23 as described later. The inverted block 25 is shown in FIG. 4 in which the center line C1 of the rear concave surface 45 is eccentric downward with respect to the center line C2 of the receiving area 23. The center line C1 of the rear concave surface 45 means a line extending in the direction of the eccentric rotation axis passing through the vertical center of the rear concave surface 45, and the center line C2 of the housing area 23 is the upper and lower sides of the housing area 23. It means a line extending in the direction of the eccentric rotation axis passing through the center of direction.

  The toggle plate 40 is pressed against the block 25 by the rearward tensile force applied from the tension rod 11 to the swing jaw 4 described above, and the block 25 is pressed against the rear frame 24. The toggle plate 40 presses the lower portion of the swing jaw 4 forward by the reaction force. The toggle plate 40 is restrained by the front toggle seat 41 and the rear toggle seat 44 so as not to drop out of the front toggle seat 41 and the rear toggle seat 44.

  As shown in FIGS. 1 and 2, a pair of wedge members 46 is interposed between the toggle block 43 and the rear frame 24. These wedge members 46 adjust the position of the toggle block 43 in the advancing and retracting direction P, and the outlet gap of the crushing chamber 5 (a gap between the lower end of the peak of the fixed tooth 3 and the lower end of the valley of the movable tooth 6) ) To adjust.

  That is, as shown in FIGS. 5 and 6, each wedge member 46 has a wedge surface 46a inclined with respect to the advancing / retracting direction P of the toggle block 43, and the wedge surfaces 46a can slide with each other. Further, a gap adjusting cylinder 47 provided outside the side frame 7 is connected to each of the wedge members 46, and each of the wedge members 46 is movable in a direction orthogonal to the advancing / retracting direction P of the toggle block 43. ing. With such a configuration, each wedge member 46 is driven by the gap adjusting cylinder 47 to move in the direction (left and right direction in FIGS. 5 and 6) orthogonal to the advancing and retracting direction P, the advancing and retracting position of the toggle block 43 Is adjusted to adjust the size of the outlet gap of the crushing chamber 5.

  Next, the operation of the present embodiment having such a configuration will be described.

  In the case of crushing the object S, first, an electric motor (not shown) is driven, and the driving force is transmitted to the pulley 9 through the belt. As a result, the swing jaw 4 rotates eccentrically.

  While the swing jaw 4 is eccentrically rotated, a tensile force by the spring 10 is applied to the lower portion of the swing jaw 4, and the lower portion of the swing jaw 4 is pressed against the toggle plate 40. As a result, the lower end portion of the movable tooth 6 provided on the swing jaw 4 performs a rocking movement with respect to the fixed tooth 3.

  Next, an object to be treated S as a raw material is introduced into the crushing chamber 5, and the introduced object to be treated S is sequentially compressed and crushed by the oscillating motion of the movable tooth 6. Among the objects S compressed and crushed, the object S having a size capable of passing through the outlet of the crushing chamber 5 is discharged from the outlet of the crushing chamber 5 as a crushed material.

  While the crushing process is performed, the lower end portion of the movable tooth 6 swings to draw an oval with a predetermined stroke, but since the short axis of the oval is short, it swings roughly linearly. It can be considered that.

  FIG. 7 schematically shows the rocking motion of the lower end portion of the movable tooth 6. The position shown by a solid line in FIG. 7 (as well as in FIG. 1) indicates the position where the movable tooth 6 is the farthest from the fixed tooth 3. In this case, the tilt angle θ (the angle with respect to the horizontal surface) of the toggle plate 40 is relatively large, which indicates that the lower portion of the swing jaw 4 is pulled backward. On the other hand, the position indicated by the two-dot chain line indicates the position where the movable tooth 6 is closest to the fixed tooth 3. In this case, the inclination angle of the toggle plate 40 is relatively small, and it is shown that the lower portion of the swing jaw 4 is pushed forward by receiving the reaction force of the toggle plate 40.

  And in FIG. 7, the exit clearance of the crushing chamber 5 is shown by the dimension L1. By adjusting the exit clearance of the crushing chamber 5, the size of the crushed product can be adjusted. When adjusting the exit clearance of the crushing chamber 5, as described above, the clearance adjusting cylinder 47 is driven to adjust the position of the wedge member 46, and the position of the toggle block 43 in the advancing / retracting direction P is adjusted.

  Further, in FIG. 7, the stroke of the lower end portion of the movable tooth 6 is shown by a dimension L2. The term “stroke” as used herein means the distance in the direction perpendicular to the tooth surface of the movable tooth 6 out of the movement allowance of the lower end portion of the valley portion of the movable tooth 6.

  By adjusting the stroke of the lower end portion of the movable tooth 6, the workpiece S can be efficiently crushed by setting the stroke according to the property of the workpiece S. In addition, in some cases, the portion to be treated can be efficiently crushed if the stroke is adjusted in accordance with the clearance of the crushing chamber 5 described above. Furthermore, the jaw crusher 1 can be prevented from being damaged by the reaction force during compression. Therefore, a method of reversing the block 25 from the state shown in FIG. 3 to the state shown in FIG. 4 will be described below, which is a disassembling operation method for adjusting the stroke of the lower end portion of the movable tooth 6.

  First, with the motor stopped, the cylinder 14 for adjusting the biasing force of the spring 10 is driven, and the tension rod 11 is released from the biasing force of the spring 10. As a result, the toggle plate 40 is released from the pressing force applied from the swing jaw 4.

  Subsequently, the lower portion of the swing jaw 4 is moved to the side of the fixed tooth 3, and the toggle plate 40 is removed from the front toggle seat 41 and the rear toggle seat 44. At this time, since the block body 25 is released from the pressing force applied from the toggle plate 40, the block body 25 is accommodated between the first guide structure 21 and the second guide structure 22 by its own weight. Move to the front end of area 23. The block 25 that has reached the front end of the receiving area 23 is locked to the stopper 30 and remains in the receiving area 23.

  Next, the stopper bolt 31 is loosened and removed, and the stopper 30 is removed from the guide member 27. As a result, the block 25 is pulled out of the housing area 23.

  Subsequently, the drawn block 25 is vertically inverted and inserted into the housing area 23.

  Thereafter, the reverse procedure to the procedure for pulling out the block body 25 described above is performed, and the disassembling operation is completed.

  When the disassembly and assembly work is completed, as shown in FIG. 4, when the center line C1 of the rear concave surface 45 of the rear toggle sheet 44 of the block 25 is viewed from the toggle plate 40 side, the accommodation area 23 Eccentrically downward with respect to the center line C2 of That is, the center line C1 of the rear concave surface 45 after reversing the block 25 is shifted downward from before the block 25 is reversed. Since the rear concave surface 45 is formed in a concave shape and the rear end of the toggle plate 40 slidably contacts the rear concave surface 45, the position of the rear end of the toggle plate 40 is the center line C1 of the rear concave surface 45. Due to the deviation, the block 25 is displaced downward from the position before the reversal. For this reason, the inclination angle θ of the toggle plate 40 decreases, and the toggle plate 40 pushes the lower portion of the swing jaw 4 forward, and the amount of retraction of the lower portion of the swing jaw 4 to the rear is limited. As a result, the stroke of the lower end portion of the movable tooth 6 is reduced.

  On the other hand, in the state before reversing the block body 25, as shown in FIG. 3, the center line C1 of the rear concave surface 45 of the rear toggle sheet 44 is eccentric upward with respect to the center line C2 of the accommodation area 23. The position of the rear end portion of the toggle plate 40 is located above the position after reversing the block 25. Therefore, the inclination angle θ of the toggle plate 40 is increased, and the amount of retraction of the lower portion of the swing jaw 4 to the rear is increased. As a result, the stroke of the lower end of the movable tooth 6 is increased.

  Thus, by inverting the block 25 in which the rear concave surface 45 is eccentric, the inclination angle θ of the toggle plate 40 can be changed, and the stroke of the lower end portion of the movable tooth 6 can be changed.

  As described above, according to the present embodiment, the block 25 which can be pulled out from the accommodation area 23 formed between the pair of guide structures 21 and 22 has a rear concave surface on which the rear end of the toggle plate 40 abuts. The center line C1 of the rear concave surface 45 is eccentric with respect to the center line C2 of the accommodation area 23. As a result, the block 25 is pulled out from the housing area 23 and vertically reversed, and inserted again into the housing area 23, and the vertical direction of the center line C1 of the rear concave surface 45 (more precisely, the toggle plate 40 The position in the vertical direction when the block 25 is viewed from the side can be shifted. Therefore, the inclination angle θ of the toggle plate 40 can be changed, and the stroke of the lower end portion of the movable tooth 6 can be easily adjusted.

  Further, according to the present embodiment, the guide structures 21 and 22 extend obliquely downward toward the swing jaw 4 and lock the block 25 at the front end of the guide structures 21 and 22. The stopper 30 is removably attached by the stopper bolt 31. The stopper bolt 31 is for attaching the stopper 30 for locking the block 25 located at the front end of the guide structures 21 and 22 to the guide structures 21 and 22, as shown in FIG. The size of the stopper bolt 31 can be reduced compared to 2 volts. For this reason, the effort for removing the stopper bolt 31 can be reduced, and the stopper bolt 31 can be easily removed. As a result, the stopper 30 can be removed and the block 25 can be easily turned upside down, and the stroke of the lower end portion of the movable tooth 6 can be easily adjusted.

Second Embodiment
Next, a jaw crusher according to a second embodiment of the present invention will be described with reference to FIGS. 8 to 14.

  The second embodiment shown in FIGS. 8 to 14 mainly differs in that a liner is interposed between the block body and the guide structure, and the other configurations are shown in FIGS. 1 to 7. It is substantially the same as the first embodiment. In FIG. 8 to FIG. 14, the same parts as in the first embodiment shown in FIG. 1 to FIG.

  In the present embodiment, the block bodies 25 are formed symmetrically in the vertical direction. That is, the center line C1 of the rear concave surface 45 of the block 25 is located at the center line of the block 25 when the block 25 is viewed from the toggle plate 40 side, and the rear concave surface 45 is It has a symmetrical shape in the vertical direction. Further, the thickness dimensions of the both end portions of the block 25 (the thickness dimensions of the portion where the guided portion 28 is formed) The size between and is smaller. A liner, which will be described later, is interposed between the block 25 and the guide structures 21 and 22 so as to fill the dimensional difference.

  A liner structure is removably attached to the block 25, and the liner structure is disposed between the block 25 and the guide member 27 of the first guide structure 21, and the block 25 and the second guide structure. It has a liner interposed at least in one of the space between the body 22 and the guide member 27. Although various structures can be adopted as the liner structure, here, the first liner structure 50 shown in FIGS. 8 to 10, the second liner structure 53 shown in FIGS. 11 and 12, and FIG. The third liner structure 56 shown in FIG. 14 will be described as an example.

  The first liner structure 50 shown in FIGS. 8 to 10 is connected to a first liner 51 interposed between the block 25 and the guide member 27 of the first guide structure 21 and the first liner 51, And a mounting portion 52 removably mounted on the toggle block 43 of the block body 25 by mounting bolts 58, 59. More specifically, the first liner 51 is interposed between the guided portion 28 of the toggle block 43 and the guide member 27. The attachment portion 52 is a first attachment plate 52a attached by the first attachment bolt 58 to the end surface (the right surface in FIG. 8) of the toggle block 43 of the block 25 and the rear surface of the toggle block 43 (the back side in FIG. And a second mounting plate 52b attached by a second mounting bolt 59 to the

  The rear surface of the toggle block 43 is provided with a receiving portion 60 for receiving the second mounting plate 52b, and the second mounting plate 52b is provided with a cutout 61 through which the second mounting bolt 59 passes. The notch 61 is formed to extend in the insertion direction of the first liner structure 50. With such a configuration, even when the second mounting bolt 59 is screwed into the screw hole 43a of the toggle block 43 in advance, a gap between the rear surface of the toggle block 43 and the head of the second mounting bolt 59 To insert the second mounting bolt 59 into the notch 61 of the second mounting plate 59 b and attach the second mounting plate 59 b to the rear surface of the toggle block 43 using the second mounting bolt 59. It has become. That is, in the present embodiment, even if the space for attaching or detaching the second mounting bolt 59 to the rear surface side of the toggle block 43 is limited, the first liner structure 50 is easily removed. It is designed to be attachable.

  The first liner 51, the first attachment plate 52a, and the second attachment plate 52b are connected and integrated so as to be orthogonal to each other. The first liner 51, the first attachment plate 52a, and the second attachment plate 52b may be formed by bending from a single plate member, or may be formed by joining different plate members by welding or the like.

  Although the first liner structure 50 has the first liner 51 between the block 25 and the guide member 27 of the first guide structure 21, the first liner structure 50 is composed of the block 25 and the second guide structure 22. There is no second liner interposed between the guide members 27. Also, on the other side of the block 25 (the end face not shown on the left side in FIG. 8), a liner structure having a shape that is horizontally reversed from the first liner structure 50 shown in FIG. It is attached. The same applies to the second liner structure 53 and the third liner structure 56 described later.

  In the example shown in FIG. 8, the first liner 51 is interposed between the block 25 and the guide member 27 of the first guide structure 21, but the guide member 27 of the block 25 and the second guide structure 22 is And the center line C1 of the rear concave surface 45 of the block 25 is the pair of guide structures 21 when the block 25 is viewed from the side of the toggle plate 40, since the second liner is not interposed therebetween. It is eccentric upward with respect to the center line C2 of the accommodation area 23 formed between 22.

  The second liner structure 53 shown in FIGS. 11 and 12 has the same structure as the first liner structure 50, except that the second liner structure 53 is attached to the attachment portion 52 mainly. The second liner 55 further includes a second liner 55 interposed between the block 25 and the guide member 27 of the second guide structure 22. Specifically, the second liner 55 is interposed between the guided portion 28 of the toggle block 53 and the guide portion 27. The thicknesses of the first liner 54 and the second liner 55 of the second liner structure 53 have substantially the same thickness, and approximately one of the thickness of the first liner 51 of the first liner structure 50. It has become / 2.

  In the example shown in FIG. 11, the first liner 54 interposed between the block 25 and the guide member 27 of the first guide structure 21, and the block 25 and the guide member 27 of the second guide structure 22. Since the thickness of the second liner 55 interposed therebetween is substantially the same, the center line C1 of the rear concave surface 45 of the block 25 is a storage area when the block 25 is viewed from the toggle plate 40 side. It is located on the centerline C2 of 23.

  The third liner structure 56 shown in FIGS. 13 and 14 has the same structure as the first liner structure 50, except that the third liner structure 56 is different from the first liner structure 50 in the main difference. A second liner 57 is interposed between the block 25 and the guide member 27 of the second guide structure 22 and not connected to the mounting portion 52. In addition, the thickness of the second liner 57 of the third liner structure 56 is substantially the same as the thickness of the first liner 51 of the first liner structure 50.

  In the example shown in FIG. 13, although the first liner is not interposed between the block 25 and the guide member 27 of the first guide structure 21, the block 25 and the guide member 27 of the second guide structure 22 The center line C1 of the rear concave surface 45 of the block 25 is the center line C2 of the accommodation area 23 when the block 25 is viewed from the side of the toggle plate 40. It is eccentric downward to

  By properly using these three types of liner structures 50, 53, 56, the center line C1 of the rear concave surface 45 of the block 25 can be changed in the vertical direction. Therefore, it is possible to adjust the stroke of the lower end portion of the movable tooth 6 by changing the position of the rear end portion of the toggle plate 40 in the vertical direction. The applicable liner structure is not limited to the three types described above, and if the sum of the thickness of the first liner and the thickness of the second liner is substantially equal, more types of liner structures are prepared. By selectively using the same, it is possible to more finely adjust the stroke of the lower end portion of the movable tooth 6.

  By the way, as shown in FIGS. 8, 11 and 13, the support for supporting the block 25 when the liner structures 50, 53, 56 are removed from the guide frame 26 of the first guide structure 21. A bolt 62 (support member) is provided. The support bolt 62 is screwed into a vertically extending screw hole 63 provided in the guide frame 26, and is rotated by rotating the support bolt 62 in a predetermined direction (clockwise direction in the case of a right-handed screw). The support bolt 62 can be raised to raise the block 25. When the support bolt 62 is rotated in the opposite direction, the support bolt 62 can be lowered to lower the block 25, and the upper end (tip) of the support bolt 62 is pulled away from the lower surface of the block 25. , Can be drawn below the upper surface of the guide frame 26. The support bolt 62 is provided at the front of the guide frame 26 and can support the block 25 when the block 25 is located at the front end of the housing area 23 and the liner structure 50, 53, 56 is removed. preferable. Furthermore, it is preferable that the guide frame 26 be provided with two support bolts 62 so that both ends of the block 25 are evenly supported and moved up and down. In addition, the support bolt 62 should just have the intensity | strength of the grade which can support and raise / lower the block body 25. As shown in FIG. Therefore, the strength required for the support bolt 62 can be reduced, and the size of the support bolt 62 can be reduced.

  Hereinafter, a method for adjusting the stroke of the lower end portion of the movable tooth 6 will be described. Here, as an example, a method for replacing the first liner structure 50 with the second liner structure 53 will be described.

  As in the first embodiment, after the cylinder 14 for adjusting the biasing force of the spring 10 is driven and the tension rod 11 is released from the biasing force of the spring 10, the toggle plate 40 is a front toggle. The seat 41 and the rear toggle seat 44 are removed. At this time, the block body 25 is moved to the front end of the accommodation area 23 by its own weight and locked to the stopper 30. At this time, the block 25 remains in the housing area 23.

  Subsequently, the tip end of the support bolt 62 is brought into contact with the lower surface of the block 25.

  Next, the first mounting bolt 58 and the second mounting bolt 59 are loosened, and the first mounting bolt 58 is removed, and the first liner structure 50 is removed from the block 25. At this time, the second mounting bolt 59 may not be removed. At this time, since the upper end of the support bolt 62 is in contact with the lower surface of the block 25, the block 25 is supported by the support bolt 62.

  Subsequently, the support bolt 62 is rotated so that the first liner 54 and the second liner 55 of the second liner structure 53 can be inserted between the block 25 and the guide structures 21 and 22 so that the block can be inserted. Lower 25. As a result, the center line C1 of the rear concave surface 45 of the block 25 is positioned on the center line C2 of the housing area 23.

  Subsequently, the second liner structure 53 is attached to the block 25 by tightening the first attachment bolt 58 and the second attachment bolt 59.

  Thereafter, the support bolt 62 is rotated and lowered, pulled away from the lower surface of the block body 25 and pulled downward from the upper surface of the guide frame 26.

  Thus, the center line C1 of the rear concave surface 45 of the block 25 is positioned at a predetermined position (here, the center of the storage area 23), and the block 25 is the first liner of the second liner structure 53. It is supported by the guide structures 21, 22 via the 54 and the second liner 55. In the present embodiment, when replacing the liner structures 50, 53, 56, it is not necessary to remove the stopper 30 as in the first embodiment. The first mounting bolt 58 and the second mounting bolt 59 may have a strength enough to mount the liner structure 50, 53, 56 on the block 25. Therefore, the strength required for the first mounting bolt 58 and the second mounting bolt 59 can be reduced, and the size of the first mounting bolt 58 and the second mounting bolt 59 can be reduced.

  As described above, according to the present embodiment, the liner structures 50, 53, 56 which are removably attached to the block 25 are disposed between the block 25 and the first guide structure 21 and between the block 25 and the first guide structure 21. It has a liner interposed between at least one of the two guide structures 22. As a result, the liner structure can be removed from the block 25 and replaced with another liner structure having a liner different from the above-mentioned liner, and the center line C1 of the rear concave surface 45 of the block 25 can be You can shift it to Therefore, the inclination angle of the toggle plate 40 can be changed, and the stroke of the lower end portion of the movable tooth 6 can be easily adjusted.

  Further, according to the present embodiment, the liner structures 50, 53, 56 are attached to the block body 25 removably connected by the mounting bolts 58, 59, which are connected to the liners 51, 54, 55, 57. It further comprises a part 52. Since the mounting bolts 58, 59 are for mounting the liner structures 50, 53, 56 to the block 25, the size of the mounting bolts 58, 59 can be reduced. For this reason, the effort for loosening or tightening the mounting bolts 58, 59 can be reduced, and the mounting bolts 58, 59 can be easily loosened or tightened. As a result, the stroke of the lower end portion of the movable tooth 6 can be easily adjusted, which can be removed easily and replaced with another liner structure.

  Further, according to the present embodiment, the first guide structure 21 is provided with the support bolt 62 for supporting the block 25 when the liner structures 50, 53, 56 are removed. As a result, the operation of removing the liner structure and replacing it with another liner structure can be efficiently performed, and the liner structure can be easily replaced.

  In the embodiment described above, an example in which the support member for supporting the block body 25 is configured by the support bolt 62 has been described. However, the present invention is not limited to this, and the support member can also be configured by, for example, an air cylinder or a hydraulic cylinder.

  As mentioned above, although the embodiment of the present invention has been described in detail, the jaw crusher according to the present invention is not limited to the above embodiment, and various modifications can be made without departing from the scope of the present invention. It is. Of course, it is also possible to partially combine the embodiments appropriately within the scope of the present invention.

DESCRIPTION OF SYMBOLS 1 jaw crusher 2 frame body 3 fixed tooth 4 swing jaw 5 crushing chamber 6 movable tooth 10 spring 21 first guide structure 22 second guide structure 23 accommodation area 25 block 27 guide member 30 stopper 31 stopper bolt 40 toggle plate 45 Rear concave surface 50 first liner structure 51 first liner 52 mounting portion 53 second liner structure 54 first liner 55 second liner 56 third liner structure 57 second liner 58 first mounting bolt 59 second mounting bolt 62 Support bolt C1 Centerline C2 of the rear concave surface Centerline of the storage area

Claims (3)

Frame body,
Fixed teeth provided on the frame body;
A swing jaw having an upper portion eccentrically rotatably supported on the frame body;
A movable tooth provided on the swing jaw and forming a crushing chamber with the fixed tooth;
A biasing portion for biasing the lower portion of the swinging jaw to the side opposite to the fixed tooth side;
A pair of guide structures provided on the frame body and separated from each other;
A block body which is interposed between the pair of guide structures and which can be pulled out from the storage area between the pair of guide structures;
And a toggle plate interposed between the swing jaw and the block body for applying a swinging motion to the swing jaw with respect to the fixed tooth.
The block body has a concave surface formed in a concave shape when viewed in the direction of the eccentric rotation axis of the swing jaw, with which the end of the toggle plate on the side of the block body abuts.
When the block body is viewed from the side of the toggle plate, in the vertical direction, the center line of the concave surface is eccentric to the center line of the accommodation area ,
The guide structure extends obliquely downward toward the swing jaws,
A locking member for locking the block body is attached to an end of the guide structure on the swing jaw side . The locking member, the end on the side of the swing jaw of the guide structure, the jaw crusher according to claim 1, characterized in that removably attached to the locking bolt. The guide structure includes a guide member for guiding the block body.
The block body can slide on each of the guide structures via the guide members,
The jaw crusher according to claim 2, wherein the locking member is removably attached to the guide member.

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