CN218809895U - Titanium ingot clamp - Google Patents

Abstract

The utility model discloses a titanium ingot anchor clamps belongs to titanium top centre gripping technical field, include: the two ends of the cross beam are symmetrically and movably connected with crank arms respectively and used for clamping two opposite sides of a titanium ingot; the pressing block is positioned between the connecting levers, and two ends of the pressing block are respectively movably connected with the connecting levers on the same side; the lower end of the power part is connected with the top of the pressing block, and the upper end of the power part penetrates through the cross beam; when the power part acts, the pressing block can be pushed to move up and down between the crank arms, and the crank arms are synchronously driven to approach or separate from each other. Can drive the briquetting through the power spare that sets up along reciprocating to drive two turning arms and be close to each other or separate, so, but the titanium ingot of centre gripping equidimension not, when pressing from both sides the titanium ingot tight back, the power that the titanium ingot was given to the briquetting is a constant force, can not be because of changing, thereby can realize the stable centre gripping to the titanium ingot through rotatory lead screw.

Description

Titanium ingot clamp

Technical Field

The utility model relates to a smelt processing machinery equipment technical field, concretely relates to titanium ingot anchor clamps.

Background

In the smelting and processing process of titanium and titanium alloy, the raw materials that are usually adopted are all blocky ingots, and the transportation handling of titanium ingot then must adopt corresponding mechanical structure to realize, for example anchor clamps, prior art, application number: CN201922282401.1, a clamp for lifting cylindrical titanium gyroscope in titanium sponge processing workshop, includes: two ends of the cross beam are respectively hinged with a group of clamping lifting appliances, the two groups of clamping lifting appliances are identical in structure and are symmetrically arranged at two ends of the cross beam, each group of clamping lifting appliances comprise two connecting rods and two clamping arms, the upper ends of the connecting rods are hinged to the same end of the cross beam, the clamping arms are arranged in a crossed manner, and the upper ends of the clamping arms are respectively hinged with the lower ends of the connecting rods; the upper end of the lock rod is hinged to the middle of the cross beam, the lower part of the lock rod is hinged to the middle of the pressure arm, and a spring is arranged between the rod-shaped end of the pressure arm and the lower part of the lock rod in a pressing mode.

When in actual use, rely on the elasticity of spring to stick together the centre gripping with titanium, then hoist anchor clamps through lifting device, carry out the transportation that titanium sticks together, elasticity is a variable force, and after long-time the use, the elasticity of spring descends, has the unstable problem of titanium stick together centre gripping, and in addition when the great titanium of centre gripping quality sticks together, the not enough of elasticity has the problem that the centre gripping can not live the titanium and sticks together.

SUMMERY OF THE UTILITY MODEL

In order to solve the problems of the prior art, the utility model provides a titanium ingot clamp, which comprises a cross beam, a clamping head and a clamping head, wherein two ends of the cross beam are respectively and symmetrically and movably connected with a crank arm for clamping two opposite sides of a titanium ingot;

the pressing block is positioned between the crank arms, and two ends of the pressing block are respectively movably connected with the crank arms on the same side;

the lower end of the power part is connected with the top of the pressing block, and the upper end of the power part penetrates through the cross beam;

when the power part acts, the pressing block can be pushed to move up and down between the crank arms, and the crank arms are synchronously driven to approach or separate from each other;

the lower end of the support is connected with the cross beam, and the upper end of the support is provided with a suspension hole for connecting with a hoisting device.

Further, the cross beam is an I-beam;

the upper ends of the two crank arms are respectively and rotatably connected with two ends of the I-shaped beam; the upper end of the power part penetrates through the middle of the I-shaped beam.

Further, the crank arm includes: two connecting plates;

the connecting plates are arranged in parallel, and the projections of the connecting plates are superposed;

the connecting plates are connected through a strut;

the lower end of the connecting plate is arc-shaped;

the connecting plates are obliquely provided with sliding chutes, and the distance between the sliding chutes on the two connecting plates is gradually increased along with the approaching of the sliding chutes to the lower ends of the connecting plates;

and the two ends of the pressing block are respectively in sliding connection with the sliding grooves on the same side.

Furthermore, the bottom of the pressing block is arc-shaped;

notches are symmetrically arranged on two sides of the pressing block;

wherein, the connecting plates are respectively positioned in the notches at the same side;

and two ends of the pressing block are respectively connected with the sliding grooves on the same side through pin shafts.

Furthermore, an anti-skid protrusion is arranged on the inner side wall of the arc-shaped position of the lower end of the connecting plate, and the anti-skid protrusion is arranged on the inner side wall of the arc-shaped position of the bottom of the pressing block.

Furthermore, the anti-skid protrusions are arranged in a plurality of vertical parallel directions and are of rectangular structures.

Further, the power part is a screw rod;

the lower end of the screw rod is connected with the top of the pressing block through a bearing, and the top of the screw rod is connected with a servo motor;

the motor is installed on the base plate, the lower extreme of base plate is provided with 2 at least telescopic links, the lower extreme of telescopic link is provided with the mounting panel, the mounting panel with the crossbeam is connected.

The utility model has the advantages that:

can drive the briquetting through the power spare that sets up along reciprocating to drive two turning arms and be close to each other or separate, so, but the titanium ingot of centre gripping equidimension not, when pressing from both sides the titanium ingot tight back, the power that the titanium ingot was given to the briquetting is a constant force, can not be because of changing, thereby can realize the stable centre gripping to the titanium ingot through rotatory lead screw.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

Fig. 1 is a schematic structural view of a perspective view provided by the present invention;

fig. 2 is a schematic front view of the present invention;

fig. 3 is a schematic side view of the present invention.

Reference numerals: the device comprises a cross beam 1, a crank arm 2, a pressing block 3, a power part 4, a sliding groove 5 and an anti-skid bump 6.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, embodiments of the present invention will be described in further detail below with reference to the accompanying drawings.

Referring to fig. 1 to 3, a titanium ingot jig includes: the device comprises a cross beam 1, wherein two ends of the cross beam 1 are respectively and symmetrically movably connected with crank arms 2 which are used for clamping two opposite sides of a titanium ingot;

the pressing block 3 is positioned between the crank arms 2, and two ends of the pressing block 3 are movably connected with the crank arms 2 on the same side respectively;

the lower end of the power part 4 is rotatably connected with the top of the pressing block 3, the upper end of the power part 4 penetrates through the cross beam 1, and the power part 4 is rotatably connected with the cross beam 1;

when the power part 4 acts, the pressing block 3 can be pushed to move up and down between the crank arms 2, and the crank arms 2 are synchronously driven to approach or separate from each other;

the lower end of the support is connected with the cross beam 1, and the upper end of the support is provided with a suspension hole for connecting with a hoisting device.

The invention of the scheme is characterized in that the connecting levers are rotatably connected to two ends of the cross beam, so that the distance between the connecting levers can be adjusted, titanium ingots with different diameters can be clamped, then the pressing block moves upwards or downwards, the pressing block is connected with the connecting levers, so that the pressing block can synchronously drive the opening or clamping process of the connecting levers when moving, after the connecting levers clamp two sides of the titanium ingots, the pressing block synchronously clamps the rear side faces of the titanium ingots, and the titanium ingots are clamped by using the stability of a triangle.

In some embodiments, the beam 1 is an i-beam;

the upper ends of the two crank arms 2 are respectively and rotatably connected with the two ends of the I-shaped beam through pin shafts; the upper end of the power part 4 penetrates through the middle part of the I-shaped beam;

the middle part of the I-beam is provided with a through hole, threads are arranged in the through hole, the power part is a screw rod, the screw rod is in threaded connection with the threaded hole, and the top of the screw rod is provided with a handle.

In some embodiments, the crank arm 2 includes: two connecting plates;

the connecting plates are arranged in parallel, and the projections of the connecting plates are overlapped;

the connecting plates are fixedly connected through a plurality of struts;

the lower end of the connecting plate is arc-shaped; the lower ends of the connecting plates are oppositely arranged;

the connecting plates are obliquely provided with sliding chutes 5, and the distance between the sliding chutes on the two connecting plates is gradually increased along with the approaching of the sliding chutes to the lower ends of the connecting plates;

the two ends of the pressing block 3 are respectively connected with the sliding grooves 5 on the same side in a sliding mode through pin shafts.

In some embodiments, the bottom of the compact 3 is rounded;

notches are symmetrically arranged on two sides of the pressing block 3;

the connecting plates are respectively positioned in the notches at the same side;

two ends of the pressing block 3 are respectively connected with the sliding grooves 5 on the same side through pin shafts.

The sliding chute is characterized in that through pin holes are formed in the positions, close to the two sides of the pressing block, of the pin holes, the pin holes are connected with the sliding chute on the same side through pin shafts, and the pin shafts are connected with the sliding chute in a sliding mode.

In some embodiments, an anti-slip protrusion 6 is fixedly arranged on the inner side wall of the arc-shaped position at the lower end of the connecting plate, and the anti-slip protrusion 6 is arranged on the inner side wall of the arc-shaped position at the bottom of the pressing block 3.

In some embodiments, the antiskid protrusions are arranged in a plurality of vertical parallel positions, and the antiskid protrusions 6 are in a rectangular structure.

The surface of the anti-skid bulge is provided with a frosted layer, and the anti-skid bulge has the effect of increasing the acting force between the crank arm and the titanium ingot, so that the clamping force of the crank arm on the titanium ingot is increased.

In some embodiments, the power member is a lead screw;

the lower end of the screw rod is connected with the top of the pressing block 3 through a bearing, and the top of the screw rod is connected with a servo motor;

the motor is installed on the base plate, the lower extreme of base plate is provided with 2 at least telescopic links, the lower extreme of telescopic link is provided with the mounting panel, the mounting panel with the crossbeam is connected.

The top of the pressing block is provided with a groove, a bearing is installed in the groove, and an inner ring of the bearing is fixedly connected with the bottom of the screw rod.

The telescopic rod mainly plays a role in supporting the motor and driving the screw rod to synchronously stretch and retract so as to drive the servo motor to move together.

The above description is only for the preferred embodiment of the present invention, and is not intended to limit the present invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included within the protection scope of the present invention.

Claims (7)

1. A titanium ingot clamp, comprising:

the two ends of the cross beam are respectively and symmetrically movably connected with crank arms which are used for clamping two opposite sides of a titanium ingot;

the pressing block is positioned between the crank arms, and two ends of the pressing block are respectively movably connected with the crank arms on the same side;

the lower end of the power part is connected with the top of the pressing block, and the upper end of the power part penetrates through the cross beam;

when the power part acts, the pressing block can be pushed to move up and down between the crank arms, and the crank arms are synchronously driven to approach or separate from each other;

the lower end of the support is connected with the cross beam, and the upper end of the support is provided with a suspension hole for connecting with a hoisting device.

2. The titanium ingot clamp of claim 1, wherein the cross beam is an i-beam;

the upper ends of the two crank arms are respectively and rotatably connected with two ends of the I-shaped beam; the upper end of the power part penetrates through the middle of the I-shaped beam.

3. The titanium ingot clamp of claim 1, wherein the crank arm comprises: two connecting plates;

the connecting plates are arranged in parallel, and the projections of the connecting plates are superposed;

the connecting plates are connected through a strut;

the lower end of the connecting plate is arc-shaped;

the connecting plates are obliquely provided with sliding chutes, and the distance between the sliding chutes on the two connecting plates is gradually increased along with the approaching of the sliding chutes to the lower ends of the connecting plates;

and the two ends of the pressing block are respectively in sliding connection with the sliding grooves on the same side.

4. The titanium ingot clamp of claim 3, wherein the bottom of the pressing block is arc-shaped;

notches are symmetrically arranged on two sides of the pressing block;

the connecting plates are respectively positioned in the notches on the same side;

and two ends of the pressing block are respectively connected with the sliding grooves on the same side through pin shafts.

5. The titanium ingot clamp of claim 4, wherein the inner side wall of the arc at the lower end of the connecting plate is provided with an anti-slip bulge, and the inner side wall of the arc at the bottom of the pressing block is provided with the anti-slip bulge.

6. The titanium ingot clamp of claim 5, wherein a plurality of the anti-slip protrusions are arranged in parallel in the vertical direction, and the anti-slip protrusions are rectangular.

7. The titanium ingot clamp of claim 1, wherein the power member is a lead screw;

the lower end of the screw rod is connected with the top of the pressing block through a bearing, and the top of the screw rod is connected with a servo motor;

the motor is installed on the base plate, the lower extreme of base plate is provided with 2 at least telescopic links, the lower extreme of telescopic link is provided with the mounting panel, the mounting panel with the crossbeam is connected.

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