CN219957400U - Cylindrical forging piece flaw detection equipment - Google Patents

Abstract

The utility model provides a cylindrical forging flaw detection device which comprises a base, a forging and a detector, wherein a first upright post is fixed at the top of one end of the base, a second upright post is fixed at the top of the other end of the base, a first rotating motor is arranged at the outer side of the first upright post, a transmission shaft of the first rotating motor is movably connected with a first positioning plate, a pushing cylinder is arranged at the outer side of the second upright post, a piston rod of the pushing cylinder penetrates through the second upright post to be connected with a second positioning plate, a bearing assembly is arranged at the top of the base, the forging is supported by the bearing assembly, a first rotating screw rod is movably arranged between the first upright post and the second upright post, a second rotating motor is arranged on the outer side wall of the upper part of the second upright post, the transmission shaft of the second rotating motor is connected with the first rotating screw rod, a sliding seat is movably meshed with the first rotating screw rod, a lifting cylinder is arranged at the bottom of the sliding seat, and the detector is arranged at the bottom of the lifting cylinder. The utility model has reasonable structure and good detection effect after adopting the scheme.

Description

Cylindrical forging piece flaw detection equipment

Technical Field

The utility model relates to the technical field of forge piece detection, in particular to cylindrical forge piece flaw detection equipment.

Background

The ultrasonic flaw detection is a method for detecting defects of parts by utilizing the characteristics that ultrasonic energy penetrates into a metal material deeply and is reflected at the edge of an interface when entering another section from the section, reflected waves are respectively generated when ultrasonic beams are led into the metal from the surface of the parts and meet the defects and the bottom surface of the parts, pulse waveforms are formed on a fluorescent screen, the positions and the sizes of the defects are judged according to the pulse waveforms, and the ultrasonic automatic flaw detection equipment is used for detecting the internal quality of steel pipes, steel bars, steel plates, steel balls and the like which are needed to be detected one by one on a steel production line, and the existing flaw detection equipment needs staff to hold the operation when in use, particularly when large annular forgings are detected, the working strength is high, and the flaw detection efficiency of forgings is influenced.

Disclosure of Invention

The utility model aims to overcome the defects of the prior art and provides the cylindrical forging flaw detection equipment which is reasonable in structure and good in detection effect.

In order to achieve the above purpose, the technical scheme provided by the utility model is as follows: the utility model provides a cylindrical forging check out test set, it is including the base, the forging, a detector, base one end top is vertical to be fixed with first stand, the vertical second stand that is fixed with in base other end top, first rotating electrical machines is installed in the first stand outside, first rotating electrical machines's transmission shaft passes first stand and first locating plate swing joint, push cylinder is installed in the second stand outside, push cylinder's piston rod passes the second stand and is connected with the second locating plate, reserve the location district between second locating plate after the installation and the first locating plate activity, the bearing subassembly is installed at the base top of location district below, the forging is supported by the bearing subassembly, movable mounting has first rotatory screw rod between first stand and the second stand of location district top, install second rotating electrical machines on the second stand upper portion lateral wall, the transmission shaft of second rotating electrical machines passes second stand and is connected with first rotatory screw rod, movable engagement has the slide on the first rotatory screw rod, the lift cylinder is installed to the slide bottom is vertical.

The bearing assembly comprises a fixed bearing seat and a movable bearing seat, wherein the fixed bearing seat is fixedly arranged at the top of a base in a positioning area, a second rotary screw rod is movably arranged between the fixed bearing seat and a second upright post, a third rotary motor is arranged on the outer side wall of the lower part of the second upright post, a transmission shaft of the third rotary motor penetrates through the second upright post to be connected with the second rotary screw rod, a threaded hole penetrating through the middle part of the movable bearing seat is arranged, the movable bearing seat is movably meshed on the second rotary screw rod through the threaded hole, a concave chute is arranged on the base below the movable bearing seat, a sliding block is formed by downwards extending the bottom of the movable bearing seat, and the sliding block is movably embedded in the chute.

The top parts of the fixed bearing seat and the movable bearing seat are provided with concave bearing grooves, and the bearing grooves of the fixed bearing seat and the movable bearing seat are respectively provided with a ball.

A guide post is fixed between the first upright post and the second upright post above the first rotary screw rod, a guide hole is formed in the upper portion of the sliding seat, and the upper portion of the sliding seat is movably sleeved on the guide post through the guide hole.

According to the technical scheme, the position of the movable bearing seat is adjusted according to the length of the forge piece to be detected, when the forge piece to be detected is long, the third rotary motor drives the second rotary screw rod to rotate clockwise through the transmission shaft, the movable bearing seat moves away from the fixed bearing seat under the action of threads, when the forge piece to be detected is short, the third rotary motor drives the second rotary screw rod to rotate anticlockwise through the transmission shaft, the movable bearing seat moves towards the fixed bearing seat under the action of threads, after the movable bearing seat is adjusted, the two ends of the forge piece to be detected are placed on the corresponding bearing seat, balls in the bearing grooves bear the ends of the forge piece to be detected, the end of the first rotary motor is contacted with the end of the first positioning plate, a piston rod of the pushing cylinder stretches out to drive the second positioning plate to abut against the end of the forge piece to be detected, the piston rod of the lifting cylinder stretches out to drive the detector to move downwards to detect the forge piece to be detected, the second rotary screw rod is driven by the first rotary screw rod to rotate under the action of threads, the first rotary screw rod is driven by the first rotary slide under the action of the threads, the forge piece to drive the forge piece to be detected to detect the forge piece to be detected is driven by the first rotary slide, the end of the forge piece to be detected is driven by the first rotary slide, the forge piece to detect the forge piece to be detected is detected at different positions, and the first position of the forge piece to be detected is detected by the rotary plate is positioned on the first positioning plate to be detected, and reasonable, and the forge piece is detected by adopting the rotary structure to have reasonable effect that the rotary structure is detected.

Drawings

Fig. 1 is a schematic diagram of the overall structure of the present utility model.

Fig. 2 is a schematic view of the installation structure of the movable bearing bracket of the present utility model.

Description of the embodiments

Embodiments of the present patent are described in detail below, examples of which are illustrated in the accompanying drawings, wherein the same or similar reference numerals refer to the same or similar elements or elements having the same or similar functions throughout. The embodiments described below by referring to the drawings are exemplary only for explaining the present patent and are not to be construed as limiting the present patent.

In the description of this patent, it should be understood that the terms "center," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate describing the patent and simplify the description, and do not indicate or imply that the devices or elements being referred to must have a particular orientation, be configured and operated in a particular orientation, and are therefore not to be construed as limiting the patent.

In the description of this patent, it should be noted that, unless explicitly stated and limited otherwise, the terms "mounted," "connected," and "disposed" are to be construed broadly, and may be fixedly connected, disposed, detachably connected, disposed, or integrally connected, disposed, for example. The specific meaning of the terms in this patent will be understood by those of ordinary skill in the art as the case may be.

The utility model is further described below with reference to all drawings, in which preferred embodiments of the utility model are: referring to fig. 1 and 2, the flaw detection device for cylindrical forgings in this embodiment includes a base 1, a forging 2, and a detector 13, wherein a first upright 3 is vertically fixed at the top of one end of the base 1, a second upright 4 is vertically fixed at the top of the other end of the base 1, a first rotating motor 5 is installed on the outer side of the first upright 3, a transmission shaft of the first rotating motor 5 penetrates through the first upright 3 to be movably connected with a first positioning plate 6, a pushing cylinder 7 is installed on the outer side of the second upright 4, a piston rod of the pushing cylinder 7 penetrates through the second upright 4 to be connected with a second positioning plate 8, a positioning area is reserved between the second positioning plate 8 and the first positioning plate 6 after installation, a supporting component is installed at the top of the base 1 below the positioning area, the forging 2 is supported by the supporting component, a first rotating screw 9 is movably installed between the first upright 3 and the second upright 4 above the positioning area, a second rotating motor 10 is installed on the outer side wall of the upper portion of the second upright 4, the transmission shaft of the second rotating motor 10 penetrates through the second upright 4 to be movably connected with the first rotating screw 9, a guide post 11 is movably meshed with the first rotating screw 11 on the first rotating screw 9, a guide post 11 is installed on the first rotating screw 11 and a guide post 11 is movably meshed with a sliding seat 11 on the first sliding seat 11, a guide post 11 is installed on the sliding seat 11 and a guide hole is installed on the sliding seat 11 is movably meshed with the sliding seat 11, and a guide hole is installed on the sliding seat 11, and the sliding seat is installed on the sliding seat 11; the bearing assembly comprises a fixed bearing seat 14 and a movable bearing seat 15, wherein concave bearing grooves 19 are formed in the tops of the fixed bearing seat 14 and the movable bearing seat 15, balls 20 are arranged in the bearing grooves 19 of the fixed bearing seat 14 and the movable bearing seat 15, the fixed bearing seat 14 is fixedly arranged on the top of the base 1 in a positioning area, a second rotary screw 16 is movably arranged between the fixed bearing seat 14 and the second upright 4, a third rotary motor 22 is arranged on the outer side wall of the lower portion of the second upright 4, a transmission shaft of the third rotary motor 22 penetrates through the second upright 4 to be connected with the second rotary screw 16, a penetrating threaded hole is formed in the middle of the movable bearing seat 15, the movable bearing seat 15 is movably meshed on the second rotary screw 16 through the threaded hole, a concave chute 17 is formed in the base 1 below the movable bearing seat 15, a sliding block 18 is formed by extending downwards at the bottom of the movable bearing seat 15, and the sliding block 18 is movably embedded in the chute 17. After the embodiment is adopted, the position of the movable supporting seat is adjusted according to the length of the forge piece to be detected, when the forge piece to be detected is longer, the third rotary motor drives the second rotary screw rod to rotate clockwise through the transmission shaft, the movable supporting seat moves away from the fixed supporting seat under the action of threads, when the forge piece to be detected is shorter, the third rotary motor drives the second rotary screw rod to rotate anticlockwise through the transmission shaft, the movable supporting seat moves towards the fixed supporting seat under the action of threads, after the movable supporting seat is adjusted, the two ends of the forge piece to be detected are placed on the corresponding supporting seat, balls in the supporting groove support, and the end part of the forge piece to be detected at one end of the first rotary motor is contacted with the first positioning plate, the piston rod of the pushing cylinder stretches out to drive the second positioning plate to clamp and position the end part of the forge piece to be detected, the piston rod of the lifting cylinder stretches out to drive the detector to move downwards to detect the forge piece to be detected, the second rotary screw rod is driven by the first rotary screw rod to rotate under the action of threads when the forge piece to be detected, the slide is driven by the first rotary screw rod to slide under the action of threads, the detector to drive the forge piece to be detected, the forge piece to be detected is detected at different positions, the first positioning plate is driven to rotate the forge piece to rotate, and the forge piece to be detected at different positions, and the first positioning plate is reasonably detected, and the position is detected, and reasonable is realized, and the rotary position is realized to rotate.

The above-mentioned embodiments are only preferred embodiments of the present utility model, and are not intended to limit the scope of the present utility model, so that all changes made in the shape and principles of the present utility model are covered by the scope of the present utility model.

Claims (4)

1. The utility model provides a cylindrical forging check out test set, it is including base (1), forging (2), detector (13), its characterized in that: the vertical first stand (3) that is fixed with in base (1) one end top, base (1) other end top is vertical to be fixed with second stand (4), first rotating electrical machines (5) are installed in first stand (3) outside, movable mounting has first rotatory screw rod (9) between first stand (3) and second stand (4) swing joint, propelling movement cylinder (7) are installed in second stand (4) outside, the piston rod of propelling movement cylinder (7) passes second stand (4) and is connected with second locating plate (8), reserve the location district between second locating plate (8) and first locating plate (6) alive after the installation, bearing subassembly is installed at base (1) top of location district below, forging (2) are supported by bearing subassembly, movable mounting has first rotatory screw rod (9) between first stand (3) and the second stand (4) of location district top, install second rotatory motor (10) on the lateral wall on second stand (4) upper portion, the transmission shaft of second rotatory motor (10) passes second stand (4) and is connected with first rotatory screw rod (9) and is connected with first rotatory screw rod (11), lift screw rod (12) are installed in first rotatory screw rod (11) bottom the vertical sliding seat (11), lift cylinder (11) is installed.

2. The cylindrical forging flaw detection apparatus as recited in claim 1, wherein: the bearing assembly comprises a fixed bearing seat (14) and a movable bearing seat (15), wherein the fixed bearing seat (14) is fixedly arranged at the top of a base (1) in a positioning area, a second rotary screw (16) is movably arranged between the fixed bearing seat (14) and a second upright (4), a third rotary motor (22) is arranged on the outer side wall of the lower part of the second upright (4), a transmission shaft of the third rotary motor (22) penetrates through the second upright (4) to be connected with the second rotary screw (16), a threaded hole penetrating through the middle part of the movable bearing seat (15) is arranged, the movable bearing seat (15) is movably meshed on the second rotary screw (16) through the threaded hole, a downward concave chute (17) is formed on the base (1) below the movable bearing seat (15), a sliding block (18) is formed by downward extending, and the sliding block (18) is movably embedded in the chute (17).

3. The cylindrical forging flaw detection apparatus as recited in claim 2, wherein: the tops of the fixed bearing bracket (14) and the movable bearing bracket (15) are provided with concave bearing grooves (19), and balls (20) are arranged in the bearing grooves (19) of the fixed bearing bracket (14) and the movable bearing bracket (15).

4. The cylindrical forging flaw detection apparatus as recited in claim 1, wherein: a guide post (21) is fixed between the first upright post (3) and the second upright post (4) above the first rotary screw (9), a guide hole which penetrates through is formed in the upper portion of the sliding seat (11), and the upper portion of the sliding seat (11) is movably sleeved on the guide post (21) through the guide hole.