CN218272055U - Frame construction that assembly line detected - Google Patents

Abstract

The utility model discloses a frame construction for assembly line detection, which comprises a control platform, a test assembly line and a measuring head assembly, wherein a fixed platform is arranged below the test assembly line, and a Y-axis driving assembly is arranged above the fixed platform; the control platform is arranged on the upper end face where the test production line is located from one side, the measuring head assembly stretches across the upper end face where the test production line is located from the other end portion and is embedded into the outer housing wrapped by the control platform, the lower end portion where the measuring head assembly is located is connected with the Y-axis driving assembly, and the measuring head assembly is integrally moved left and right in the Y-axis direction where the test production line is located through driving of the Y-axis driving assembly. Through adjusting the measuring head subassembly that sets up, can realize the position adjustment in two directions of Y, Z, greatly improved the detection efficiency that multi-angle position detected.

Description

Frame construction that assembly line detected

Technical Field

The utility model belongs to the technical field of detect auxiliary assembly, concretely relates to frame construction that assembly line detected.

Background

At present, most X-ray fluorescence spectrometers on the market can only detect a single sample piece, because the position of the X-ray fluorescence spectrometer is relatively fixed, only one point position of the sample piece can be detected during each detection, when a plurality of point positions need to be detected, the relative position of the sample piece needs to be adjusted, and when the positions of the sample pieces are manually adjusted one by one, the efficiency is low and the labor cost is high; the part realizes that the instrument of on-line measuring also replaces the manual work to take along with the line sample spare through robotic arm, and is higher to the operation precision of manipulator, causes the damage of colliding with of sample spare in the transport transportation of making a round trip easily.

Meanwhile, a plurality of groups of X-ray fluorescence spectrometers in different directions are arranged on the same production line for detection, the investment cost of equipment is additionally increased, a sample piece needs to be detected through a plurality of procedures when being detected, and the detection time of the sample piece is prolonged.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art, the utility model aims to provide a frame construction that assembly line detected has solved the above-mentioned technical problem who exists among the prior art.

The purpose of the utility model can be realized by the following technical proposal:

a frame structure for assembly line detection comprises a control platform, a test assembly line and a measuring head assembly, wherein a fixed platform is arranged below the test assembly line, and a Y-axis driving assembly is arranged above the fixed platform;

the control platform is arranged on the upper end face where the test production line is located from one side, the measuring head assembly stretches across the upper end face where the test production line is located from the other end portion and is embedded into the outer housing wrapped by the control platform, the lower end portion where the measuring head assembly is located is connected with the Y-axis driving assembly, and the measuring head assembly is integrally moved left and right in the Y-axis direction where the test production line is located through driving of the Y-axis driving assembly.

Furthermore, the test assembly line comprises a base and a conveyor belt, wherein the base is used for supporting the transversely arranged conveyor belt, and the conveyor belt is used for conveying the test samples.

Furthermore, the base is integrally arranged on the side where the Y-axis driving component is arranged.

Further, Y axle drive assembly includes a set of driving motor and sets up the lead screw spare at the driving motor tip, another tip at lead screw spare place is connected in the measuring head subassembly bottom, through the rotation of driving motor drive lead screw spare to drive the measuring head subassembly and remove along the extending direction of lead screw spare.

Furthermore, a Z-axis driving assembly is arranged on the measuring head assembly, and the measuring head assembly is driven to adjust in the Z-axis direction through the Z-axis driving assembly.

Furthermore, the Y-axis driving assembly further comprises a slide rail, and the extension direction of the slide rail is the same as that of the screw rod piece and is in sliding connection with the bottom of the measuring head assembly.

The utility model has the advantages that:

1. the Y-axis driving assembly is matched with the Z-axis driving assembly arranged on the measuring head assembly, so that the measuring head assembly is adjusted in two directions of the Y axis and the Z axis respectively, multi-angle scanning photographing detection can be performed on sample pieces in a transmission state, the direction of the sample pieces is not required to be adjusted in multiple processes, and the detection efficiency is improved.

2. The measuring head assembly of the device is embedded in a shell wrapped by the control platform, so that the limited process area occupied by the measuring instrument is reduced, and the radiation of the measuring head assembly can be reduced by wrapping the control platform, so that unnecessary protection injury is brought to operators.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below.

Fig. 1 is a schematic diagram of the overall structure of the embodiment of the present invention;

fig. 2 is a schematic diagram of an explosive structure according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of a part at position a according to an embodiment of the present invention.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention. Based on the embodiments of the present invention, all other embodiments obtained by a person skilled in the art without making creative efforts belong to the protection scope of the present invention.

As shown in fig. 1 and fig. 2, the embodiment of the utility model provides a frame construction that assembly line detected, including controlling platform 1, test assembly line 2, measuring head assembly 3, the below at test assembly line 2 place is provided with fixed platform 4, and the top that is located fixed platform 4 place is provided with Y axle drive assembly 41. The test assembly line 2 comprises a base 21 and a conveyor belt 22, wherein the base 21 is used for supporting the conveyor belt 22 which is transversely arranged, the test samples are transmitted through the conveyor belt 22, and the test samples on the conveyor belt 22 are continuously transmitted, so that the transmission efficiency is greatly improved.

The control platform 1 is placed on the upper end face of the test line 2 from one side, and the measuring head assembly 3 spans the upper end face of the test line 2 from the other end and is embedded in the outer casing wrapped by the control platform 1, so that the control platform 1 is integrally placed above the conveyor belt 22 of the test line 2, transmission of the test sample by the conveyor belt 22 is not affected, and the measuring head assembly 3 is wrapped in the outer casing of the control platform 1.

As shown in fig. 3, the base 21 is integrally disposed at a side position where the Y-axis driving assembly 41 is located, a lower end portion where the measuring head assembly 3 is located is connected to the Y-axis driving assembly 41, the Y-axis driving assembly 41 includes a set of driving motor 411 and a screw rod 412 disposed at an end portion of the driving motor 411, another end portion where the screw rod 412 is located is connected to a bottom portion of the measuring head assembly 3, and the driving motor 411 drives the screw rod 412 to rotate, so as to drive the measuring head assembly 3 to move along an extending direction of the screw rod 412 (i.e., move left and right in the Y-axis direction). Meanwhile, the measuring head assembly 3 is provided with a Z-axis driving assembly 31, and the measuring head assembly 3 is driven to adjust in the Z-axis direction through the Z-axis driving assembly 31. Realize the offset of Y axle, Z axle and X axle direction (being the direction of transmission that conveyer belt 22 drove the sample spare) simultaneously, can realize being located the testing arrangement multi-angle of measuring head assembly 3 and testing the sample spare on conveyer belt 22, need not the multi-process operation of doing over again, greatly improved detection efficiency.

The Y-axis driving assembly 41 further includes a sliding rail 413, and the sliding rail 413 extends in the same direction as the screw rod 412 and is slidably connected to the bottom of the measuring head assembly 3, so as to reduce the frictional resistance of the measuring head assembly 3 when sliding along the Y-axis direction.

The foregoing shows and describes the basic principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention.

Claims (6)

1. A frame structure for assembly line detection comprises a control platform (1), a test assembly line (2) and a measuring head assembly (3), and is characterized in that a fixed platform (4) is arranged below the test assembly line (2), and a Y-axis driving assembly (41) is arranged above the fixed platform (4);

control the up end that test assembly line (2) place in from one side in platform (1), simultaneously measuring head subassembly (3) span the up end at test assembly line (2) place and imbed in controlling the outer housing that platform (1) wrapped up from another tip, the lower tip at measuring head subassembly (3) place is connected with Y axle drive assembly (41) to through the drive of Y axle drive assembly (41), realize that measuring head subassembly (3) wholly moves about along the Y axle direction at test assembly line (2) place.

2. A frame structure for in-line testing according to claim 1, characterized in that the testing line (2) comprises a base (21), a conveyor belt (22), the base (21) being adapted to support the transversely arranged conveyor belt (22) for transporting the test sample through the conveyor belt (22).

3. The frame structure for pipeline inspection according to claim 2, wherein the base (21) is integrally disposed at a side where the Y-axis driving assembly (41) is disposed.

4. The framework structure for pipeline inspection according to claim 1, wherein the Y-axis driving assembly (41) comprises a set of driving motors (411) and screw rods (412) disposed at ends of the driving motors (411), the other ends of the screw rods (412) are connected to the bottom of the measuring head assembly (3), and the driving motors (411) drive the screw rods (412) to rotate, so as to drive the measuring head assembly (3) to move along the extending direction of the screw rods (412).

5. The frame structure for pipeline inspection according to claim 1, wherein the measuring head assembly (3) is provided with a Z-axis driving assembly (31), and the Z-axis driving assembly (31) is used for driving the adjustment of the measuring head assembly (3) in the Z-axis direction.

6. The frame structure for pipeline inspection according to claim 4, wherein the Y-axis driving assembly (41) further comprises a sliding rail (413), and the sliding rail (413) extends in the same direction as the screw rod (412) and is slidably connected to the bottom of the measuring head assembly (3).

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