DE1151428B - Jaw crusher with hydraulic power transmission device - Google Patents

Description

Jaw crusher with hydraulic power transmission device The invention relates to jaw crusher with hydraulic power transmission device, consisting of from a drive piston reciprocated in a cylinder and one via a Pressure member acting on the movable jaw (crushing rocker) driven piston.

In the known jaw crushers, the force is applied to the crushing arm Transferred via a simple pressure piece, which is in a rounding of the crushing arm is arranged. Because the forces to be transmitted are extremely high and so far a satisfactory solution to the lubrication problem for the thrust piece bearing was not found could be, a very heavy wear was the inevitable result.

The invention is based on these disadvantages of the previous Eliminate jaw crusher. Changes in jaw crushers of the type mentioned above the hydraulic pressure that occurs during the working strokes of the pressure piston and the Working piston is developed, among other things, depending on the type and amount of the material being crushed between the jaws.

According to the invention, this variable pressure is now used, to transmit the impact between the involved surfaces lying on top of one another and to the extent to which the shock due to fluid pressure in the bearing clearance or other Gaps between these superposed surfaces is transmitted, the Shock transmission between these surfaces through direct contact between them to reduce it to a minimum or to switch it off completely and thus reduce wear, caused by the contact of metal on metal can be reduced to a minimum or to avoid it altogether.

Accordingly, the invention is characterized in that between the pressure transmission member and the crushing rocker a hydrostatic bearing arranged is, whose pressure chamber is acted upon with the corresponding pressure during the working stroke will.

A particularly advantageous embodiment of the invention is distinguished characterized in that the bearing point between the pressure transmission member and the drive piston is designed as a hydrostatic bearing.

The pressure chambers of the hydrostatic bearings are advantageously located in connection with the pressure chamber of the output cylinder via channels.

The effective areas are in a further embodiment of the invention the pressure chambers of the hydrostatic bearings smaller than the effective area of the output piston.

However, you can also choose the construction so that the effective Areas of the pressure chambers of the hydrostatic bearings are larger than the effective ones Surface of the output piston, being in the connecting channels between the pressure chambers and adjustable throttle points are provided in the pressure chamber of the output cylinder.

The training can also be made so that the pressure chamber of the Bearing point on the output piston has a smaller effective area and the pressure chamber the bearing point on the crushing arm has a larger effective area than the effective Has surface of the output piston.

Resilient seals are advantageous for sealing the pressure chambers provided that allow a tilting movement of the pressure member.

Finally, the transmission device is advantageously designed in such a way that that the bearing points are formed spherically and the pressure member only rests with its outer edge on the spherical counter surface and thereby the limitation the pressure chambers forms.

An advantageous exemplary embodiment is shown below with reference to the drawing of the invention described.

Fig. 1 shows schematically a jaw crusher according to the invention; Fig. 2 shows a side view, partially in section, a corresponding to the invention Facility for Transmission of the shock from the output piston to the Crushing arm.

1 shows the conditions under which a pressure member 8; that the Transferring crushing forces from the output piston 4 to the jaw 2, works. Of the Jaw crusher has a fixed jaw 1 and a movable jaw or crushing rocker 2, which is pivotably mounted at its upper end by means of a shaft 3. Of the The output piston 4 arranged in a cylinder 5 transmits the movement to the movable jaw 2. A reciprocating drive piston 6 generates the pressure in a drive piston chamber. A pressure member 8 transmits the pressure from the output piston 4 on the crushing arm 2. As can be seen from the drawing, the link 8 leads slight movements with respect to both the rocker arm 2 and the output piston 4 and must therefore be articulated at both ends.

A special construction of the pressure member shown schematically 8, in which the shock developed in whole or in part by the in the output piston cylinder Fluid pressure is transmitted is shown in FIG. You can see that Pressure member 8 arranged between the output piston 4 and a part 13 of the crushing rocker is. The output cylinder 5 stands in with the drive cylinder through the opening 9 Link.

The bearing construction 14 between the pressure member and the output piston comprises a convex surface 15 in a socket 16 provided in the output piston 4 and a flat surface 17 in contact with the surface 15 at the end of the pressure member B. In this way, a pressure chamber 18 is between the output piston and the pressure member is formed which, in order to reduce the forces mechanically transmitted between the surfaces 15 and 17, is connected to the output cylinder through a channel 19 in the output piston. A leakage of hydraulic fluid from the chamber 18 is prevented by the sealing ring 20 or other sealing means.

The breaking movement of the rocker arm 2 is generated in part by the pressure which is transmitted hydraulically from the output piston 4 to the surface 17. A corresponding reaction force acts on the output piston. Only the force that corresponds to the product of the pressure in the output cylinder with the difference between the cross section of the output piston and the impact surface 17 is transmitted mechanically from the output piston to the pressure member 8. In this way, any portion of the breaking force that is smaller than its totality can be transmitted hydraulically.

The back and forth movement of the pressure member is almost straight in the direction of its axis, and its angulation with respect to the output piston is very small indeed.

The movement of the pressure member 8 relative to the moving jaw 2 is, however not insignificant, so that a slightly different bearing construction 21 at the other end Des. Pressure member is provided.

The bearing structure 21 comprises a spherically convex surface 22 provided on a rocker part 13 and a spherically concave surface 23 resting thereon at the end of the pressure member. A recess in the surface 23 forms a pressure chamber 24 between the surfaces 22 and 23. The cross section of this pressure chamber is slightly larger than that of the output piston and therefore takes up the majority of the two opposing surfaces 22 and 23. The pressure chamber 24 is connected to the pressure chamber 18 and thus also to the output cylinder through a channel 25 in the pressure member. The flow through the channel 25 is controlled by a throttle 26. This can consist of a screw seated loosely in a threaded hole 27 at the end of the channel 25.

If the abutting surfaces 22 and 23 were held in firm contact, no flow could take place between them and also through the channel 25. There would therefore be no pressure drop there, and the full pressure prevailing in the output cylinder would be transmitted to the intermediate space and act on the bearing surface 22 of the rocker.

However, since the cross section of the pressure chamber 24 is larger than that of the output piston, an excess of force occurs, which tends to remove the adjacent Surfaces 22 and 23 to be separated from each other. These therefore move slightly apart, and there is a flow of oil between them and through the restriction 26. With this throttling, therefore, a pressure drop occurs, the size of which depends on the extent the flow through it is dependent. The separation of surfaces 22 and 23 each other also depends on this measure.

The pressures in the pressure chamber 24 and in the oil film in the bearing clearance between the supporting surfaces are therefore set in such a way that the entire output piston The hydraulic force transmitted to the supporting surface 22 of the rocker is equal to the is the force transmitted by the pressure member. All of the exerted on the swingarm Shock is therefore applied to them by the hydraulic pressure generated by the drive piston transfer. Between the mutually abutting surfaces moved relative to one another Storage therefore does not actually come into contact during operation, so that these surfaces are also not subject to wear and tear.

The flow of hydraulic oil of ordinary viscosity required is to keep the bearing surfaces 22 and 23 out of contact is very small and is controlled by the throttle 26.

The pressure member can be in a dust cover 28 made of oil-proof rubber or similar material may be included, loosely between the moving Extends jaw and the output piston cylinder.

The surfaces 22 and 23 can also be cylindrical instead of spherical Have shape. However, spherical bearing surfaces have the advantage that they are also adjust automatically when the jaw moves transversely or in rotation.

Claims (1)

PATENT CLAIMS: 1. Jaw crusher with hydraulic power transmission device, consisting of a drive piston reciprocated in a cylinder and a Output piston acting via a pressure element on the movable crusher jaw (crusher rocker), characterized in that between the pressure transmission member (8) and the crushing rocker (2) a hydrostatic one Storage (22 to 24) is arranged, its Pressure chamber (24) is pressurized during the working stroke will. z. Jaw crusher according to Claim 1, characterized in that the bearing point (14) between the pressure transmission member (8) and the output piston (4) as a hydrostatic Bearing is formed. 3. Jaw crusher according to claim 2, characterized in that that the pressure chambers (18,24) of the hydrostatic bearings via channels (19, 25) with are connected to the pressure chamber of the output cylinder (5). 4. Jaw crusher after Claim 2 or 3, characterized in that the effective surfaces of the pressure chambers (18, 24) of the hydrostatic bearings (14, 21) are smaller than the effective area of the output piston (4). 5. Jaw crusher according to claim 3, characterized in that that the effective areas of the pressure chambers (18, 24) of the hydrostatic bearings (14, 21) are larger than the effective area of the output piston (4), whereby in the connecting channels (19, 25) adjustable between the pressure chambers and the pressure chamber of the output cylinder (5) Throttle points (27) are provided. 6. Jaw crusher according to claim 2 or 3, characterized characterized in that the pressure chamber (18) of the bearing point (14) on the output piston (4) a smaller effective area and the pressure chamber (24) of the bearing point (21) on the crushing arm (2) has a larger effective area than the effective area of the Has output piston (4). 7. Jaw crusher according to one of claims 1 to 6, characterized in that resilient ones for sealing the pressure chambers (18, 24) Seals (20) are provided which allow a tilting movement of the pressure member (8). B. jaw crusher according to one of claims 1 to 7, characterized in that the Bearing points (14, 21) are designed in the shape of a spherical surface and the pressure member (8) only rests with its outer edge (23) on the spherical counter surface (22) and thereby forming the delimitation of the pressure chambers (18, 24). Considered publications: U.S. Patent Nos. 2,609,994, 2,620,629.