ITTO960911A1 - ADJUSTABLE STROKE CONNECTION. - Google Patents

Description

DESCRIPTION

of the patent for Industrial Invention of

BACKGROUND OF THE INVENTION

1. Field of the invention.

The present invention relates to mechanical stamping and drawing presses and, more particularly, to a device for an adjustable stroke connection for adjusting the stroke length of the press slide.

2. Description of the related technique. In mechanical presses it is often desirable to adjust or change the stroke length of a reciprocating element, for example the slide, on which a stamping tool is installed. In some prior art gear adjustment systems, there is a tendency to wear parts of the system # after a certain period of time of operation. It may be desirable to provide an apparatus or system which can be used to quickly easily and accurately adjust the stroke length of the slide or other parts.

SUMMARY OF THE INVENTION

The present invention provides a double eccentric adjustable stroke linkage system for use in changing the stroke length of the slide or other element of a mechanical press.

An eccentric with an eccentric bushing is mounted on a rotating crankshaft. A press connecting element, such as a connecting rod or joint, is connected around the eccentric bushing. In normal operation, there is relative movement between the eccentric bushing and the connecting member or arm thereby causing reciprocating movement of the press slide. During stroke adjustment, pressurized oil is communicated between the eccentric bushing and the crankshaft eccentric, relieving the press connection or keying with mutual interference, causing expansion of the eccentric bushing and forming a temporary press connection with the link arm. At this point, the crankshaft can rotate, together with its eccentric, to thus change the position of the eccentric inside the eccentric bushing. This causes a change in stroke length. The oil pressure is then decreased thereby causing the eccentric bushing to contract and re-forming an interference press connection with the crankshaft eccentric and freeing the temporary press connection between the outside of the eccentric bushing and the connecting element or arm. After the high oil pressure has been reduced, normal press operation can proceed.

The invention comprises, in one of its forms, a mechanical press having a connecting element of the press, an eccentric bushing disposed inside the connecting element of the press, and a second eccentric element disposed inside the eccentric bushing, the second eccentric element connectable in a detachable way with the eccentric bushing. A rotating crankshaft is connected to the second eccentric member. The invention comprises means for connecting the eccentric bushing with the connecting element of the press to prevent its reciprocal rotation and to allow the rotation of the second eccentric element inside the eccentric bushing, whereby the rotation of the crankshaft, when the medium is activated, causing an adjustment of the press stroke. The invention also includes at least one seal with a high coefficient of friction, arranged between the second eccentric element and the eccentric bushing, in which the high friction seal prevents rotation of the eccentric bushing with respect to the second eccentric element before the creation of the press connection. temporary.

The invention comprises, in another form thereof, a fluid pressure means for connecting the eccentric bushing with the connecting element of the press to prevent rotation therebetween and allow rotation of the second eccentric element within the eccentric bushing. The fluid pressure means includes fluid passages through the crankshaft in communication with a fluid pressure intensifying means for increasing the fluid pressure through the crankshaft passages. In one form of the invention, the intensifier may comprise a movable piston for increasing the pressure of the fluid within the passages of the crankshaft.

An advantage of the present invention is that a mechanical press can now comprise a simple and compact stroke adjusting link operated by fluid pressure. Previous stroke adjustment links utilize keys and / or gears between the crankshaft and various eccentrics. The present invention utilizes a linkage which is simple in design and greatly reduces the number of parts required for a stroke adjustment mechanism.

Another advantage of the present invention is that a significant cost reduction is achieved together with an increase in the functionality of the press with a simple stroke adjustment link. In addition, maintenance costs for adjustment and replacement parts, compared to previous adjustable stroke links, are reduced.

Another advantage of the present invention is a fluid intensifier which enables a high fluid intensification ratio to be obtained while located within the crankshaft of the press. The new fluid intensifier of the present invention is simple in construction and operation, thus requiring simple rotational seal arrangements.

BRIEF DESCRIPTION OF THE DRAWINGS

The aforementioned and other features and advantages of this invention, and the manner of obtaining them, will become more apparent and the invention will be better understood with reference to the following description of embodiments of the invention, together with the accompanying drawings, in which:

Figure 1 is a partially broken away schematic perspective view of a portion of the crankshaft and the slide connection;

Figures 2A and 2B are two cross sections of the crankshaft and the eccentric bushing, respectively in the maximum and minimum stroke positions, in which the connection is shown in projection, and in which the oil ducts for lubrication and crankshaft adjustment are not shown;

Figure 3 is an enlarged view of the crankshaft and the eccentric bushing of Figure 2A;

Figures 4A and 4B are schematic axial cross sections of the invention at different times of operation, i.e., respectively, during normal molding operations and during stroke / eccentric length adjustment;

Figure 5 is a schematic axial cross section of an alternative embodiment of the invention, showing an additional connecting bushing between the eccentric bushing and the link, and with an oil duct for crankshaft adjustment;

Figure 6A is an axial cross section of a first eccentric bushing. Figures 6B and 6C are respectively an axial cross section and a side view of another eccentric bushing. Figure 6D is an axial cross section of yet another eccentric bushing.

Figure 7 is an axial cross section of an embodiment of the present invention in which a suitable method of supplying high pressure oil to the crankshaft is shown, without a high pressure rotating connection;

Figure 8 is a schematic partial cross section of a second sealing configuration for sealing the high pressure oil between the eccentric bushing and the crankshaft eccentric; Figure 9 is a projection view of a typical mechanical press utilizing the present invention; And

Figure 10 is a schematic cross section of one of the U-shaped seals of the present invention.

Corresponding reference characters indicate corresponding parts in the various views. Although the drawings represent embodiments of the invention, the drawings are not necessarily to scale and certain features may be exaggerated or omitted to better illustrate and explain the present invention.

DESCRIPTION OF THE REALIZATIONS

The adjustable stroke linkage of the present invention is ideally suited for a wide variety of mechanical stamping press configurations. As is conventional, a mechanical press 110 (Fig. 9) typically comprises a traverse part 115, a bed part 117 to which a mold holder assembly is connected, and uprights 113 which connect the traverse part 115 and the bed part 117. The uprights 113 are connected or integral with the lower side of the crosspiece and the upper side of the bed. A slide 119 is positioned between the uprights 113 to perform a guided reciprocating movement with respect to the bed. Tie rods (not shown), which extend across the crosshead, up and toward the bed part, are connected at each end with tie rod bolts. Leg elements 118 are formed as an extension of the bed and are generally mounted to the floor by means of shock absorbing blocks.

To drive reciprocating movement of slide 119, a drive mechanism 114 is provided for the press. A suitable mechanism includes a drive motor 116 connected by means of a belt to an auxiliary flywheel 120 connected to the cross member 115. The auxiliary flywheel 120 is connected to a main flywheel 112, which in turn is selectively engaged by the clutch of the clutch combination. The brake for controlling the rotation of the crankshaft 14 of the press, which in turn effects a sliding movement by means of links extending between the slide and the crankshaft. This description of the press 110 and its drive mechanism is merely illustrative. A wide variety of mechanical presses are well known in the art, and the present invention can be used with any mechanical press that uses a crankshaft type device to achieve reciprocating motion of a press component. An example of a mechanical press is described in U.S. Pat. n. 5,189,928 entitled "PUNCH PRESS WITH ADJUSTABLE STROKE", which is incorporated herein by reference.

Referring now to FIG. 1, a portion of the crankshaft, its associated eccentric bushing, and the link which is actuated by rotation of the crankshaft are schematically shown in perspective. The connection can be formed of a lower part and an upper part, and the lower part of the connection element 10 must typically be suitably connected to the press slide. The crankshaft 14 comprises a cylindrical main part 16 axially centered on the axis of rotation of the crankshaft, and a second eccentric element such as a cylindrical eccentric 18 rotatably fixed thereto or integrally formed therewith. Although only one crankshaft cam is shown, more cams along the axial length of the crankshaft 14 may be provided to cooperate with additional links which are not shown.

Eccentric 18 surrounding the crankshaft is an eccentric bushing 20 in bronze. Figs. 2A, 2B and 3 better illustrate the configuration of these components, in which the main part 16 of the crankshaft is shown with dashed lines. During normal operation of the press, when the crankshaft 14 rotates, the eccentric bushing 20 is held in position on the eccentric 18 of the crankshaft (i.e. rotates with it) by means of a press connection or interference fit around to the circumference of the crankshaft eccentric at 22 which is sufficient to transmit the torque required to perform the molding or forming operation. To lubricate the rotation of the eccentric bushing 20 with respect to the connection 10, oil is supplied. For example, the oil passes through the top of the connection or connection head into the conduit 24 and into a radial port 26 from 0.003 "to 0.005", to provide a film of oil over which the eccentric bushing 20 rotates. 4A shows how oil, at 125 psi, can be distributed through the flexible tubing 25 and the conduit 24 to the radial slide port 26 to lubricate the movement of the link. At this point of operation, the ducts in Fig. 4A indicated by dashed lines inside the crankshaft 14 and eccentric 18 are not used to effect the stroke adjustment described further below. When the crankshaft 14 and its co-rotating eccentric bushing 20 rotate with respect to the connection 10, the connection 10 moves up and down to effect an alternative movement of the slide 119.

When a change or adjustment of the stroke of the slide 119 is desired, the rotation of the crankshaft 14, and hence the movement of the slide, is stopped, and the oil supplied through the conduit 14 to the top of the link 10 is stopped. Then, the high pressure oil is fed through the crankshaft 24 through the axial hole 28 and one or more transverse holes 29, towards the inside diameter of the eccentric bushing 20. The high pressure oil should be, without being limited to these values, between 7,000 psi and 10,000 psi, and is distributed circumferentially around - the eccentric 18 of the crankshaft. Seals 100, 102, such as along the axial edges in the inner diameter of the bushing 20, may be provided to prevent leakage of the high pressure oil. The high pressure oil tends to circularly expand the bushing 20 to lift the press connection between the crankshaft eccentric 18 and the eccentric bushing 20. The high pressure oil actually creates a small radial gap, indicated at 31, between the eccentric 20 and the eccentric 18 of the crankshaft, and creates a situation of press connection or keying with temporary interference at 33, circumferentially between the eccentric bushing 20 and the connection 10. (See also the Fig.4B). The lubricated radial opening 31 allows the crankshaft 14 to rotate with respect to the eccentric bushing 20 which, due to its temporary press connection with the connecting element 10, does not rotate. As the crankshaft 14 rotates, the main part 16 of the crankshaft moves to a different position with respect to the eccentric bushing 20, which in turn actually changes the stroke length of the link 10 to a desired length. When the adjustment is completed, the high pressure oil 31 supplied through the crankshaft 14 is stopped, allowing the eccentric bushing 20, due to the elasticity of the metal of its construction, to return into its press connection with the eccentric of the crankshaft (second eccentric element 18) to allow the rotation of the crankshaft again to alternately move the connection and then continue the molding operations.

Figs. 2A and 2B illustrate how with a 180 ° rotation of the crankshaft 14 together with the eccentric bushing 20, a stroke length of 2.5 "is obtained, as shown. Of course, within the scope of the invention they are other stroke lengths possible.

Fig. 5 describes an alternative embodiment of the invention, and this embodiment is shown during the molding operations. In this embodiment, an additional connecting bushing 11 is interposed between the connection 10 and the bushing 20, and the connecting bushing 11 is inserted into a circumferential groove obtained in the radially external part of the eccentric bushing 20. The oil can be introduced into the radial light 26 to provide an oil film which facilitates the free rotation of the crankshaft and its eccentric bushing with respect to the connection 10 and its associated bushing 11. In this embodiment, the seals 35 prevent the escape of high pressure oils from the space between the crankshaft eccentric 18 and the eccentric bushing 20. During stroke adjustment, high pressure oil is supplied through multiple transverse holes 29 fed through an axial hole 28. Axial hole 28 extends through the crankshaft to each link, as well as along the axial length of the crankshaft.

To help prevent the possibility of ovalization of the eccentric bushing 20 and develop uneven stresses when it expands to lift its press connection with the crankshaft eccentric 18 as described above, a variety of bushing shapes can be employed. eccentric.

For example, Fig.6A is an axial cross section of an eccentric bushing 20 in which the eccentric lobe portion 40 includes an internal cavity 41 in fluid communication with the internal opening 43 of the eccentric bushing which receives the eccentric 18 of the 'crankshaft. When the high pressure oil is introduced circumferentially around the crankshaft eccentric, the high pressure oil provides a radially outward directed force (as indicated by arrows 42), and the force also acts on the crankshaft. interior of lobe cavity 41, as shown. Fig. 6B is a cross section, conceptually similar to the view of Fig. 6A, in which the outer lobe part has a double T beam shape with a central rib 45. The forces produced by the high pressure oil are again indicated at 42. Fig. 6C describes the eccentric bushing of Fig. 6B in side view, in which the eccentric lobe is shown including the rib 45 lowered with respect to the axial edges of the eccentric bushing. Fig. 6D describes yet another embodiment in axial cross section, in which the eccentric lobe 47 of the eccentric bushing 20 is hollow.

Referring now to Fig. 7, there is shown yet another aspect of the present invention which permits a conventional rotational union, as opposed to the special high pressure rotational union, to be used to introduce high pressure oil used for the expansion of the eccentric bushing. Most of the embodiment shown in Fig. 7 is conceptually similar to the embodiments described above. A cylindrical cam 52 of the crankshaft is integral with the main part 50 of the crankshaft and surrounded by an eccentric bushing 54 which is press-connected at 55 on the cam 52. A connecting bushing 56 surrounds the eccentric bushing 54 and is equipped with a small radial opening at 60. The connecting bushing 56 is press-connected inside an opening formed between the connecting head 63 and the connecting bottom 62, which is attached to the press slide.

A hole 65 extends through the main part 50 of the crankshaft from which transverse holes 67 branch out and extend radially through the eccentric 52 of the crankshaft. The axial hole 65 extends to the left in Fig. 7 towards the other connections. To allow the high pressure oil used to expand the eccentric bushing 54 without requiring oil at these high pressures to be introduced through a rotating connection in the crankshaft, an intensifier with a ratio of 10: 1 is provided. (or other relationship). Within the end of the axial bore 65 is an intensifier rod or plunger 69 which is sealed by the seal 70 abutting in an internal groove of the crankshaft. Alternatively, the seal may be mounted on the plunger 69. The plunger 69 terminates with the circumferentially sealed piston 72. The oil, for example at 1,000 psi, passes from 74 in the spin union 76 and chamber 78 where it acts against the piston 72 to force the plunger 69 to move to the left. During the movement of the plunger, the air passes through the exhaust 79.

When the plunger 69 has a cross-sectional area of one tenth, or other fraction, of the cross-sectional area of the piston 72, the oil that is already inside the axial hole 65 and the transverse holes 67 is carried at a pressure of approximately 10,000 psi by the movement of the piston. The piston and plunger are designed to have sufficient travel to allow enough oil to move to provide expansion of the eccentric bushings of all links. As the high pressure oil within the transverse holes 67 moves into the inner diameter cavity of the eccentric bushing 54 to radially expand the bushing, the seals 81 prevent oil from leaking or seeping out of the closed system.

Fig. 8 is a partial axial cross section of another method of sealing the high pressure oil used to expand the eccentric bushing. In this embodiment, O-ring face seals 84 mounted on the eccentric bushing 86 cooperate with radially aligned walls of the ribs 88 projecting from the eccentric 90 of the crankshaft. Or, the seals may be provided on ribs 88 for protection against oil leaks. In the scope of this invention, other forms of the seal may be used.

The present invention comprises two seals 100 and 102 (Fig. 1 and 10) made of a material with a high coefficient of friction which, when pressurized, creates a sealing force or mechanism such that the eccentric bushing 20 and the second eccentric element 18 are clamp together to form a press connection or a keying with interference in the gap 26, which is located between the connection element 10 and the eccentric bushing 20.

The coupling torque, during the rotation of the crankshaft 14, will exceed the high coefficient of friction of this characteristic, thus created between the eccentric element 18 and the eccentric bushing 20. This characteristic allows several eccentrics to move simultaneously with the same angle, without any additional toothed mechanism, sprockets, or other mechanisms to ensure proper synchronization or displacement therebetween. This sealing arrangement, with a high coefficient of friction, also reduces parts and simplifies the design. There are no other mechanical parts necessary to maintain the position of several eccentrics relative to each other, so that the slide remains parallel after the change in the stroke of the press has been completed.

An additional feature of the invention is that the same adjustable stroke connection can be used between the crankshaft and a rocker arm, whereby the balancing of the press can be maintained. Hence, the types of connecting elements usable with the present invention may be those of a normal connecting arm or other joint to a part of the press, such as a dynamic balance wheel.

Although the adjustable stroke mechanism of the present invention uses a single oil passage through the crankshaft, it may be possible to have two different oil passages arriving from opposite sides, one to operate the link mechanism, to stroke adjustable of the present invention with respect to the slides, and the other passage that performs stroke adjustment for a balanced arrangement.

One type of seal that has been found useful in the present invention is the U-type seal. This type of seal operates by the action of internal fluid pressure to expand the edges of the seal. This movement creates a braking force between the eccentrics and the bed pin which allows a locking force to be developed. A U or U cup seal has been found to perform better than any other type of seal used heretofore. Figure 10 shows a typical U-shaped seal (100, 102) while pressure is applied between two eccentric elements. The clamping force increases with pressure. The holding force can then be easily manipulated for whatever torque is required for the device.

While the present invention has been described with a preferred design, the present invention may be further modified in the spirit and scope of this disclosure. This application is therefore intended to cover any variations, uses or adaptations of the invention using its general principles. Furthermore, the present application intends to cover the variations from the present description which fall within the known or ordinary practice of the art to which the invention belongs and which fall within the limits of the attached claims.

Claims (15)

CLAIMS 1. Mechanical press comprising: a connecting element of the press; an eccentric bushing arranged inside said connecting element of the press; a second eccentric element disposed inside said eccentric bushing, said second eccentric element connectable in a detachable manner with said eccentric bushing; a rotating crankshaft connected to said second eccentric element; And means for connecting said eccentric bushing with said connecting element of the press to prevent rotation therebetween and allow the rotation of said second eccentric element inside said eccentric bushing, whereby the rotation of said crankshaft, when said medium is activated, it can cause an adjustment of the press stroke. 2. Press according to claim 1, wherein said connecting means comprises fluid pressure applied to the interface between said second eccentric element and said eccentric bushing, whereby said pressure allows relative rotation between said second eccentric element and said eccentric bushing. 3. A press according to claim 1, wherein said connecting means comprises fluid pressure applied to the interface between said second eccentric element and said eccentric bushing and causing mutual connection between said eccentric bushing and said press connection by means of a press connection. temporary. 4. Press according to claim 3, wherein said means operates through said crankshaft. 5. Press according to claim 3, further comprising at least one high friction seal disposed between said second eccentric element and said eccentric bushing, whereby said high friction seal prevents rotation of said eccentric bushing with respect to said second eccentric element before creating of said temporary press link. 6. Press according to claim 5, wherein said high friction seal comprises a U-shaped seal. 7. Press according to claim 1, wherein said means operates through said crankshaft. 8. Press according to claim 1, wherein said eccentric bushing comprises an internal cavity in communication with said second eccentric element. 9. Press according to claim 1, wherein said eccentric bushing comprises a rib with a double T beam cross section. 10. Mechanical press comprising: a connecting element of the press; an eccentric bushing arranged inside said connecting element of the press; a second eccentric element disposed inside said eccentric bushing, said second eccentric element connectable in a detachable way with said eccentric bushing; a rotating crankshaft connected to said second eccentric element; fluid pressure means for connecting said eccentric bushing with said press connection means for preventing rotation therebetween and permitting rotation of said second eccentric member within said eccentric bushing, said fluid pressure means comprising fluid passages through said crankshaft in communication with a fluid pressure intensifying means for increasing fluid pressure through said crankshaft passages. 11. A press according to claim 10, wherein said fluid pressure intensifier comprises a movable piston for increasing the fluid pressure within said crankshaft passages. 12. Press according to claim 10, wherein said fluid pressure means comprises fluid pressure applied to the interface between said second eccentric element and said eccentric bushing, whereby such pressure permits relative rotation between said second eccentric element and said bushing eccentric. 13. A press according to claim 10, wherein said connecting means comprises fluid pressure applied to the interface between said second eccentric element and said eccentric bushing and causing mutual connection between said eccentric bushing and said press connection by means of a press connection temporary. 14. Press according to claim 13, further comprising at least one high friction seal disposed between said second eccentric element and said eccentric bushing, whereby said high friction seal prevents rotation of said eccentric bushing with respect to said second eccentric element before creating of said temporary press link. 15. A press according to claim 15, wherein said high friction seal comprises a U-shaped seal.