HYDRAULIC ROLLING-CUT SHEARS

Abstract

A hydraulic rolling-cut shears, including: a horizontally disposed hydraulic cylinder; a shear mechanism including an upper tool post and a lower tool post; a linkage mechanism including a first upper connecting rod, a first lower connecting rod, a second upper connecting rod, a second lower connecting rod, and a synchronous connecting rod; and supports including a hydraulic cylinder support and a guiding rod support. The hydraulic cylinder is hinged to and disposed on the hydraulic cylinder support through a first pin. One end of the first upper connecting rod, one end of the first lower connecting rod, and one end of the synchronous connecting rod are hinged to one end of a piston rod of the hydraulic cylinder via a second pin. The first upper connecting rod, the synchronous connecting rod, and the first lower connecting rod are disposed at one side of the hydraulic cylinder support.

Description

BACKGROUND OF THE INVENTION

Field of the Invention

The invention relates to a hydraulic rolling-cut shears.

Description of the Related Art

Typically, there are two kinds of rolling-cut shears: mechanical shears and hydraulic shears.

The mechanical shears are bulky, require high machining and assembling accuracy, have complex transmission system, high power consumption, high production, operation, and maintenance costs.

The hydraulic shears include two horizontally disposed hydraulic cylinders configured to drive the linkage mechanism. The two hydraulic cylinders are controlled by a servo control system, which requires high-level hardware to ensure the stability of the control system. Thus, the hydraulic shears are expensive and costly to maintain.

SUMMARY OF THE INVENTION

In view of the above-described problems, it is one objective of the invention to provide a rolling-cut shears driven by a single hydraulic cylinder.

To achieve the above objective, in accordance with one embodiment of the invention, there is provided a hydraulic rolling-cut shears, comprising: a horizontally disposed hydraulic cylinder, a shear mechanism, a linkage mechanism, and supports.

The hydraulic cylinder is hinged to and disposed on a hydraulic cylinder support through a first pin. An end of a piston rod of the hydraulic cylinder is hinged to one end of a first upper connecting rod, one end of a first lower connecting rod, and one end of a synchronous connecting rod via a second pin. The first upper connecting rod, the synchronous connecting rod, and the first lower connecting rod are disposed at one side of a hydraulic cylinder support, and are disposed from top to bottom in that order. The other end of the synchronous connecting rod is hinged to one end of a second upper connecting rod and one end of a second lower connecting rod via a third pin. The second upper connecting rod and the second lower connecting rod are disposed at one side of the guiding rod support. The other end of the first upper connecting rod and the other end of the second upper connecting rod are hinged to an upper beam via a fourth pin. The other end of the first lower connecting rod and the other end of the second lower connecting rod are hinged to an upper tool post.

An angle between the first upper connecting rod and a perpendicular line is defined as β. An angle between the first lower connecting rod and the perpendicular line is defined β₁. An angle between the second upper connecting rod and the perpendicular line is defined as α. An angle between the second lower connecting rod and the perpendicular line is defined as α₁. One end of a guiding rod is hinged to the upper tool post, and the other end of the guiding rod is hinged to the guiding rod support. An angle between the guiding rod and a horizontal line is defined as φ, and φ is 5 degrees.

When in use, the horizontally disposed hydraulic cylinder drives the first upper connecting rod, the first lower connecting rod, and the synchronous connecting rod, and the synchronous connecting rod operates to transmit power to the second upper connecting rod and the second lower connecting rod, therefore, a synchronous movement of the first upper connecting rod, the first lower connecting rod, the second upper connecting rod, the second lower connecting rod, and the synchronous connecting rod is achieved, and the upper tool post is driven to conduct rolling cut. Whether the piston rod is stretched out or retracted, the rolling cut on metal sheet is conducted. The first upper connecting rod, the first lower connecting rod, the second upper connecting rod, and the second lower connecting rod are not in alignment with one another.

In a class of this embodiment, structure parameters of the rolling-cut shear driven by a single hydraulic cylinder during the rolling cut are as follows:

A distance H from a first hinge joint connecting the first upper connecting rod and the upper beam to a second hinge joint connecting the second upper connecting rod and the upper beam is between 1000 and 5000 mm.

The first upper connecting rod and the first lower connecting rod have an equal length M, and M is between 200 and 2500 mm.

The second upper connecting rod and the second lower connecting rod have an equal length N, and N is between 200 and 2500 mm.

The angle β between the first upper connecting rod and the perpendicular line and the angle β₁ between the first lower connecting rod and the perpendicular line are equal, and are between −25 degrees and 25 degrees.

The angle α between the second upper connecting rod and the perpendicular line and the angle α₁ between the second lower connecting rod and the perpendicular line are equal, and are between −35 degrees and 35 degrees.

Advantages of the hydraulic rolling-cut shears according to embodiments of the invention are summarized as follows:

• • 1. The rolling-cut shear uses one horizontally disposed hydraulic cylinder to drive the four connecting rods, achieving the synchronous movement of the four connecting rods. The rolling-cut shear performs the rolling cut under the control of the guiding rod. During the rolling cut, the hydraulic cylinder moves within the limit position under control, and no servo control system is required. The shear features a compact structure, and the hydraulic system and the control system have moderate costs and are convenient for maintenance.
  • 2. During the rolling cut of the shear, the linkage mechanism has a good reinforcement effect; to be specific, the shear force of the hydraulic cylinder is twice the thrust force thereof, thus saving the energy and reducing the emission.
  • 3. Whether the piston rod of the hydraulic cylinder is stretched out or retracted, the rolling cut on the metal sheet is conducted, which greatly improves the service efficiency of the shear.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic diagram of a rolling-cut shear driven by a single hydraulic cylinder in accordance with one embodiment of the invention;

FIG. 2 is a diagram showing a cut-in process of a rolling-cut shear driven by a single hydraulic cylinder when a hydraulic cylinder is stretched out in accordance with one embodiment of the invention;

FIG. 3 is a diagram showing a rolling-cut process of a rolling-cut shear driven by a single hydraulic cylinder when a hydraulic cylinder is stretched out in accordance with one embodiment of the invention;

FIG. 4 is a diagram showing a cut-out process of a rolling-cut shear driven by a single hydraulic cylinder when a hydraulic cylinder is stretched out in accordance with one embodiment of the invention;

FIG. 5 is a diagram showing a cut-off process of a rolling-cut shear driven by a single hydraulic cylinder when a hydraulic cylinder is stretched out in accordance with one embodiment of the invention;

FIG. 6 is a diagram showing a cut-in process of a rolling-cut shear driven by a single hydraulic cylinder when a hydraulic cylinder is retracted in accordance with one embodiment of the invention;

FIG. 7 is a diagram showing a rolling-cut process of a rolling-cut shear driven by a single hydraulic cylinder when a hydraulic cylinder is retracted in accordance with one embodiment of the invention;

FIG. 8 is a diagram showing a cut-out process of a rolling-cut shear driven by a single hydraulic cylinder when a hydraulic cylinder is retracted in accordance with one embodiment of the invention; and

FIG. 9 is a diagram showing a cut-off process of a rolling-cut shear driven by a single hydraulic cylinder when a hydraulic cylinder is retracted in accordance with one embodiment of the invention.

In the drawings, the following reference numbers are used: 1. Upper beam; 2. First upper connecting rod; 3. Synchronous connecting rod; 4. Second upper connecting rod; 5. Second lower connecting rod; 6. First lower connecting rod; 7. Hydraulic cylinder; 8. Hydraulic cylinder support; 9. Guiding rod support; 10. Guiding rod; 11. Upper tool post; 12. Metal sheet; and 13. Lower tool post.

DETAILED DESCRIPTION OF THE EMBODIMENTS

Example 1

As shown in FIGS. 1-9, a rolling-cut shear driven by a single hydraulic cylinder comprises: a horizontally disposed hydraulic cylinder, a shear mechanism, a linkage mechanism, and supports. The hydraulic cylinder 7 is hinged to and disposed on a hydraulic cylinder support 8 through a first pin. An end of a piston rod of the hydraulic cylinder 7 is hinged to one end of a first upper connecting rod 2, one end of a first lower connecting rod 6, and one end of the synchronous connecting rod 3 via a second pin. The first upper connecting rod, the synchronous connecting rod, and the first lower connecting rod are disposed at one side of the hydraulic cylinder support 8, and are disposed from top to bottom in that order. The other end of the synchronous connecting rod 3 is hinged to one end of the second upper connecting rod 4 and one end of the second lower connecting rod 5 via a third pin. The second upper connecting rod and the second lower connecting rod are disposed at one side of the guiding rod support 9. The other end of the first upper connecting rod and the other end of the second upper connecting rod are hinged to an upper beam 1 via a fourth pin. The other end of the first lower connecting rod and the other end of the second lower connecting rod are hinged to an upper tool post 11. An angle between the first upper connecting rod 2 and a perpendicular line is defined as β. The first upper connecting rod is disposed at one side of the hydraulic cylinder support 8. An angle between the first lower connecting rod 6 and the perpendicular line is defined as β₁. The first lower connecting rod is disposed at one side of the hydraulic cylinder support 8, and β=β₁=−25°-25° . An angle between the second upper connecting rod 4 and the perpendicular line is defined as α. The second upper connecting rod is disposed at one side of guiding rod support 9. An angle between the second lower connecting rod 5 and the perpendicular line is defined as α₁. The second lower connecting rod is disposed at one side of the guiding rod support 9, and α=α₁=−35°-35° . One end of a guiding rod 10 is hinged to the upper tool post 11, and the other end of the guiding rod is hinged to the guiding rod support 9. An angle between the guiding rod 10 and a horizontal line is defined as φ, and φ is 5 degrees. When the cutting begins, a distance from the piston rod of the hydraulic cylinder 7 to a bottom of the hydraulic cylinder is defined as L. The piston rod of the hydraulic cylinder 7 is stretched out, and drives the first upper connecting rod 2, the first lower connecting rod 6, and the synchronous connecting rod 3 which are disposed at one side of the hydraulic cylinder support 8, and the synchronous connecting rod 3 operates to transmit power to the second upper connecting rod 4 and the second lower connecting rod 5 which are disposed at one side of the guiding rod support 9, therefore, a synchronous movement of the first upper connecting rod, the first lower connecting rod, the second upper connecting rod, and the second lower connecting rod is achieved, and the upper tool post 11 is driven to conduct rolling cut, then the metal sheet 12 fixed at the lower tool post 13 is cut. As shown in FIG. 2, when the distance from the piston rod of the hydraulic cylinder 7 to the bottom of the hydraulic cylinder is L1, the sheer is in the cut-in process. As shown in FIG. 3, when the distance from the piston rod of the hydraulic cylinder 7 to the bottom of the hydraulic cylinder is L2, the sheer is in the rolling-cut process. As shown in FIG. 4, when the distance from the piston rod of the hydraulic cylinder 7 to the bottom of the hydraulic cylinder is L3, the sheer is in the cut-out process. As shown in FIG. 5, when the distance from the piston rod of the hydraulic cylinder 7 to the bottom of the hydraulic cylinder is L4, the sheer is in the cut-off process. The rolling cut can be conducted when the piston rod of the hydraulic cylinder is retracted, and as shown in FIG. 6, when the distance from the piston rod of the hydraulic cylinder 7 to the bottom of the hydraulic cylinder is L3, the sheer is in the cut-in process; as shown in FIG. 7, when the distance from the piston rod of the hydraulic cylinder 7 to the bottom of the hydraulic cylinder is L2, the sheer is in the rolling-cut process; as shown in FIG. 8, when the distance from the piston rod of the hydraulic cylinder 7 to the bottom of the hydraulic cylinder is L1, the sheer is in the cut-out process; and as shown in FIG. 9, when the distance from the piston rod of the hydraulic cylinder 7 to the bottom of the hydraulic cylinder is L, the sheer is restored to the initial state.

The first upper connecting rod 2, the first lower connecting rod 6, the second upper connecting rod 4, and the second lower connecting rod 5 are not in alignment with one another. The first upper connecting rod and the first lower connecting rod are disposed at one side of the hydraulic cylinder support 8, and the second upper connecting rod and the second lower connecting rod are disposed at one side of the guiding rod support 9. The angle between the first upper connecting rod 2 which is disposed at one side of the hydraulic cylinder support 8 and the perpendicular line is different from the angle between the second upper connecting rod 4 which is disposed at one side of the guiding rod support 9 and the perpendicular line, and the difference is between 5 degrees to 15 degrees.

Ranges of the key structure parameters of the sheer in the example are as follows:

A distance H from a first hinge joint connecting the first upper connecting rod 2 and the upper beam to a second hinge joint connecting the second upper connecting rod 4 and the upper beam is between 1000 and 5000 mm.

The first upper connecting rod 2 and the first lower connecting rod 6 have an equal length M, and M is between 200 and 2500 mm.

The second upper connecting rod 4 and the second lower connecting rod 5 have an equal length N, and N is between 200 and 2500 mm.

The angle β between the first upper connecting rod 2 and the perpendicular line and the angle β₁ between the first lower connecting rod 6 and the perpendicular line are equal, and are between −25 degrees and 25 degrees.

The angle α between the second upper connecting rod 4 and the perpendicular line and the angle α₁ between the second lower connecting rod 5 and the perpendicular line are equal, and are between −35 degrees and 35 degrees.

The ranges of optimized parameters of the rolling-cut sheer driven by a single hydraulic cylinder in terms of different specifications are as shown in Table 1:

TABLE 1
Shear				β, β1	α, α1
specifications	H (mm)	M (mm)	N (mm)	(β = β1)	(α = α1)
Type 2000	1000-1800	200-850	200-850	−25°-25°	−35°-35°
Type 2500	1200-2500	400-1100	400-1100	−25°-25°	−35°-35°
Type 3200	1500-3200	550-1500	550-1500	−25°-25°	−35°-35°
Type 4000	2000-4100	650-2000	650-2000	−25°-25°	−35°-35°
Type 5000	2500-5000	700-2500	700-2500	−25°-25°	−35°-35°
Note:
1. The shear specifications are named according to the width dimensions (unit: mm) of the steel plate.
2. H is the distance from a first hinge joint connecting the first upper connecting rod 2 and the upper beam to a second hinge joint connecting the second upper connecting rod 4 and the upper beam.
3. M is the length of the first upper connecting rod 2 and the first lower connecting rod 6.

• • N is the length of the second upper connecting rod 4 and the second lower connecting rod 5.
  • 4. β is the angle between the first upper connecting rod 2 and the perpendicular line, and β₁ is the angle between the first lower connecting rod 6 and the perpendicular line.
  • 5. α is the angle between the second upper connecting rod 4 and the perpendicular line, and α₁ is the angle between the second lower connecting rod 5 and the perpendicular line.

Claims

1. A hydraulic rolling-cut shears, comprising: a horizontally disposed hydraulic cylinder;a shear mechanism comprising an upper tool post and a lower tool post;a linkage mechanism comprising a first upper connecting rod, a first lower connecting rod, a second upper connecting rod, a second lower connecting rod, and a synchronous connecting rod; andsupports comprising a hydraulic cylinder support and a guiding rod support;whereinthe hydraulic cylinder is hinged to and disposed on the hydraulic cylinder support through a first pin;one end of the first upper connecting rod, one end of the first lower connecting rod, and one end of the synchronous connecting rod are hinged to one end of a piston rod of the hydraulic cylinder via a second pin;the first upper connecting rod, the synchronous connecting rod, and the first lower connecting rod are disposed at one side of the hydraulic cylinder support, and are disposed from top to bottom in that order;the other end of the synchronous connecting rod is hinged to one end of the second upper connecting rod and one end of the second lower connecting rod via a third pin;the second upper connecting rod and the second lower connecting rod are disposed at one side of the guiding rod support;the other end of the first upper connecting rod and the other end of the second upper connecting rod both are hinged to an upper beam via a fourth pin;the other end of the first lower connecting rod and the other end of the second lower connecting rod are both hinged to an upper tool post;an angle between the first upper connecting rod and a perpendicular line is defined as β; an angle between the first lower connecting rod and the perpendicular line is defined as β1; an angle between the second upper connecting rod and the perpendicular line is defined as α; an angle between the second lower connecting rod and the perpendicular line is defined as α1;one end of a guiding rod is hinged to the upper tool post, and the other end of the guiding rod is hinged to the guiding rod support; an angle between the guiding rod and a horizontal line is defined as φ, and φ is 5 degrees;when in use, the hydraulic cylinder drives the first upper connecting rod, the first lower connecting rod, and the synchronous connecting rod, and the synchronous connecting rod transmits power to the second upper connecting rod and the second lower connecting rod, so that a synchronous movement of the first upper connecting rod, the first lower connecting rod, the second upper connecting rod, the second lower connecting rod, and the synchronous connecting rod is achieved, driving the upper tool post to conduct rolling cut; whether the piston rod is stretched out or retracted, the rolling cut on metal sheet is conducted; and the first upper connecting rod, the first lower connecting rod, the second upper connecting rod, and the second lower connecting rod are not in alignment with one another.

2. The shear of claim 1, having the following structure parameters: a distance H from a first hinge joint connecting the first upper connecting rod and the upper beam to a second hinge joint connecting the second upper connecting rod and the upper beam is between 1000 and 5000 mm;the first upper connecting rod and the first lower connecting rod have an equal length M, and M is between 200 and 2500 mm;the second upper connecting rod and the second lower connecting rod have an equal length N, and N is between 200 and 2500 mm;the angle β between the first upper connecting rod and the perpendicular line and the angle β1 between the first lower connecting rod and the perpendicular line are equal, and are between −25 degrees and 25 degrees; andthe angle α between the second upper connecting rod and the perpendicular line and the angle α1 between the second lower connecting rod and the perpendicular line are equal, and are between −35 degrees and 35 degrees.