CN217143744U - Two-way location structure of crossbeam - Google Patents

Abstract

The utility model discloses a bidirectional positioning structure of a beam, which comprises a base, wherein a pressing arm which can rotate and is pressed above the beam is arranged on the base; when the pressure arm presses the cross beam, the positioning part of the pressure arm faces the cross beam and can be abutted against the cross beam; one side of the base towards the cross beam is provided with a positioning piece which can push the cross beam to transversely support the positioning part tightly. By adopting the utility model, the beam is pressed from the vertical direction by arranging the pressing arm, so as to limit the position of the beam in the vertical direction; the transverse beam is fixed at the transverse position through the matching of the positioning piece and the positioning part, so that the transverse beam can be determined in two directions through the structure; when the crossbeam is laid, the crossbeam is placed beside the base, the pressing arm is rotated to press the crossbeam, and then the positioning piece pushes the crossbeam to move towards the positioning part so as to fix the positions of the crossbeam in two directions, so that the structure is simple and the adjustment is convenient.

Description

Bidirectional positioning structure of cross beam

Technical Field

The utility model relates to a crossbeam location field, especially a two-way location structure of crossbeam.

Background

The existing beam has the problem that the positioning structure is complex in the installation process, so that the positioning is inconvenient.

Disclosure of Invention

The utility model aims to provide a: the bidirectional positioning structure of the beam capable of being quickly positioned is provided for solving the problems of complex positioning structure and inconvenient positioning in the prior art.

In order to realize the purpose of the utility model, the utility model provides a following technical scheme:

a bidirectional positioning structure of a beam comprises a base, wherein a pressing arm which can rotate and is pressed above the beam is arranged on the base; when the pressure arm presses the cross beam, the positioning part of the pressure arm faces the cross beam and can be abutted against the cross beam; one side of the base towards the cross beam is provided with a positioning piece which can push the cross beam to transversely support the positioning part tightly.

The utility model adopting the technical proposal compresses the beam from the vertical direction by arranging the pressure arm to limit the position of the beam in the vertical direction; the transverse beam is fixed at the transverse position through the matching of the positioning piece and the positioning part, so that the transverse beam can be determined in two directions through the structure; when the crossbeam is laid, the crossbeam is placed beside the base, the pressing arm is rotated to press the crossbeam, and then the positioning piece pushes the crossbeam to move towards the positioning part so as to fix the positions of the crossbeam in two directions, so that the structure is simple and the adjustment is convenient.

Furthermore, the abutting surface of the positioning part and the cross beam is an arc surface, and the positioning part and the cross beam are in linear abutting. The linear butt reduces the area of contact of location portion and crossbeam, is convenient for press the arm to compress tightly the crossbeam after rotatory, reduces the resistance when pressing the arm rotatory.

Furthermore, the pressure arm is T-shaped, and the positioning parts are positioned at two ends of the T-shaped transverse structure of the pressure arm. Two positioning parts are arranged and have a certain distance, so that the positioning of the cross beam is more accurate.

Further, the T-shaped bottom of the pressure arm is connected with the first power piece through a connecting rod structure. The first power part provides rotary power for the pressure arm, and the cylinder can be selected as the first power part.

Furthermore, a transverse limiting piece is arranged above the base along the vertical direction, and the transverse limiting piece is trapezoidal and perpendicular to the horizontal direction towards one side of the cross beam. The transverse limiting part is used for being abutted to the cross beam, when the cross beam is automatically placed, the mechanical arm can be used for moving the cross beam to be abutted to the transverse limiting part, then the cross beam is vertically put down along the position, then the pressing arm is rotated to compress the cross beam, and then the positioning part is enabled to push the cross beam to move and enable the cross beam to be abutted to the positioning part, so that the positioning in two directions of the cross beam is completed.

Furthermore, the pressure arm is arranged in the middle of the base, and positioning pieces are arranged at two ends of the base. The middle part of the cross beam is stressed, and the two sides of the cross beam are stressed by thrust, so that the stress of the cross beam is balanced.

Further, the positioning part is connected with a second power part. The positioning piece provides power through the second power piece and pushes the positioning piece to move.

Further, the second power member is a cylinder.

To sum up, owing to adopted above-mentioned technical scheme, the beneficial effects of the utility model are that:

the cross beam is pressed from the vertical direction through the pressing arm, so that the position of the cross beam in the vertical direction is limited; the transverse beam is fixed at the transverse position through the matching of the positioning piece and the positioning part, so that the transverse beam can be determined in two directions through the structure; when the crossbeam is laid, the crossbeam is placed beside the base, the pressing arm is rotated to press the crossbeam, and then the positioning piece pushes the crossbeam to move towards the positioning part so as to fix the positions of the crossbeam in two directions, so that the structure is simple and the adjustment is convenient.

Drawings

The accompanying drawings, which form a part of the present application, are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the invention and not to limit the invention. In the drawings:

fig. 1 shows a top view of the bidirectional positioning structure of the cross beam of the present invention.

Fig. 2 shows a side view of fig. 1.

Fig. 3 shows a perspective view of the workpiece of fig. 1 with parts omitted.

Wherein the figures include the following reference numerals:

10. a base; 20. a cross beam; 30. pressing the arm; 31. a positioning part; 40. a positioning member; 50. a first power member; 60. a lateral limit piece; 70. a second power member.

Detailed Description

It is noted that, unless otherwise indicated, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs.

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.

As shown in fig. 1 to 3, in particular, when the beam 20 is placed, the beam 20 may be moved in an automatic manner using a robot arm; specifically, the cross beam 20 is moved to abut against the transverse limiting member 60 by using a mechanical arm, then the cross beam 20 is vertically put down along the position, then the first power member 50 provides power for the pressing arm 30, so that the pressing arm 30 rotates and presses the cross beam 20, then the second power member 70 pushes the positioning member 40 to move transversely, that is, the positioning member 40 pushes the cross beam 20 to move and makes the cross beam 20 abut against the positioning portion 31, at this time, the cross beam 20 is transversely positioned between the positioning member 40 and the positioning portion 31, and thus, the positioning of the cross beam 20 in two directions is completed.

A bidirectional positioning structure of a beam comprises a base 10, wherein a press arm 30 which can rotate and is pressed above a beam 20 is arranged on the base 10; when the pressing arm 30 presses the cross beam 20, the positioning portion 31 of the pressing arm 30 is disposed toward the cross beam 20 and can abut against the cross beam 20; the side of the base 10 facing the cross beam 20 is provided with a positioning member 40, and the positioning member 40 can push the cross beam 20 to laterally abut against the positioning portion 31.

By adopting the technical scheme, the cross beam 20 is pressed from the vertical direction by arranging the pressing arm 30 so as to limit the position of the cross beam 20 in the vertical direction; the positioning piece 40 is matched with the positioning part 31 to fix the transverse beam 20 at the transverse position, so that the transverse beam 20 can be determined in two directions by the structure; when the cross beam 20 is placed, the cross beam 20 is placed beside the base 10, the pressing arm 30 is rotated to press the cross beam 20, and then the positioning member 40 pushes the cross beam 20 to move towards the positioning portion 31, so that the positions of the cross beam 20 in two directions are fixed, the structure is simple, and the adjustment is convenient.

Furthermore, the contact surface between the positioning portion 31 and the cross beam 20 is a curved surface, and the positioning portion 31 and the cross beam 20 are in linear contact. The linear abutment reduces the contact area between the positioning part 31 and the cross beam 20, facilitates the rotation of the pressure arm 30 after pressing the cross beam 20, and reduces the resistance of the pressure arm 30 during the rotation.

Further, the pressing arm 30 is T-shaped, and the positioning portions 31 are located at both ends of the T-shaped lateral structure of the pressing arm 30. Two positioning portions 31 are provided, and the two positioning portions 31 have a certain distance, so that the positioning of the cross beam 20 is more accurate.

Further, the T-shaped bottom of the pressing arm 30 is connected to the first power member 50 through a link structure. The first power member 50 can be an air cylinder, and the first power member 50 can provide rotating power for the pressure arm 30.

Further, a lateral limiting member 60 is disposed above the base 10 along the vertical direction, and the lateral limiting member 60 is trapezoidal and perpendicular to the horizontal direction on a side facing the cross beam 20. The transverse limiting piece 60 is used for abutting against the cross beam 20, when the cross beam 20 is automatically placed, the cross beam 20 can be moved to abut against the transverse limiting piece 60 by using a mechanical arm, then the cross beam 20 is vertically put down along the position, then the pressing arm 30 is rotated to press the cross beam 20, then the positioning piece 40 pushes the cross beam 20 to move, and the cross beam 20 abuts against the positioning part 31, so that the positioning of the cross beam 20 in two directions is completed.

Further, the pressing arm 30 is disposed in the middle of the base 10, and the two ends of the base 10 are both provided with the positioning members 40. The middle part of the cross beam 20 is stressed, and the two sides of the cross beam 20 are stressed with thrust, so that the cross beam 20 is stressed in a balanced manner.

Further, a second power member 70 is connected to the positioning member 40. The positioning member 40 is powered by the second power member 70 and urges the positioning member 40 to move.

Further, the second power member 70 is a cylinder.

The scope of the present invention is defined not by the above-described embodiments but by the appended claims and equivalents thereof.

The above description is only a preferred embodiment of the present application and is not intended to limit the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application.

Claims (8)

1. The bidirectional positioning structure of the cross beam is characterized by comprising a base (10), wherein a press arm (30) which can rotate and is pressed above the cross beam (20) is arranged on the base (10); when the pressure arm (30) presses the cross beam (20), the positioning part (31) of the pressure arm (30) is arranged towards the cross beam (20) and can be abutted against the cross beam (20); one side of the base (10) facing the cross beam (20) is provided with a positioning piece (40), and the positioning piece (40) can push the cross beam (20) to transversely abut against the positioning part (31).

2. The bidirectional positioning structure of a cross beam according to claim 1, wherein an abutting surface of the positioning portion (31) with the cross beam (20) is an arc surface, and the positioning portion (31) is linearly abutted with the cross beam (20).

3. The bidirectional positioning structure of a cross beam according to claim 1, wherein the pressing arm (30) has a T-shape, and the positioning portions (31) are located at both ends of the T-shaped lateral structure of the pressing arm (30).

4. A bi-directional beam positioning structure according to claim 3, characterized in that the T-shaped bottom of the pressing arm (30) is connected to the first power member (50) by a link structure.

5. The beam bidirectional positioning structure according to claim 1, wherein a lateral stopper (60) is vertically disposed above the base (10), and the lateral stopper (60) has a trapezoidal shape and a side facing the beam (20) is perpendicular to a horizontal direction.

6. The bidirectional positioning structure of a beam according to claim 1, wherein the pressing arm (30) is provided in the middle of the base (10), and the positioning members (40) are provided at both ends of the base (10).

7. The bi-directional positioning structure of a crossmember according to claim 1, wherein a second power member (70) is connected to the positioning member (40).

8. The bidirectional positioning structure of a crossmember according to claim 7, characterized in that the second power member (70) is a cylinder.

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