CN216925379U - Double-guide-rail lifter sliding frame relative position detection tool - Google Patents

Abstract

The utility model discloses a double-guide-rail lifter sliding frame relative position detection tool which comprises an X-direction sliding rail, a first X-direction sliding component and a second X-direction sliding component, wherein the first X-direction sliding component and the second X-direction sliding component are both connected onto the X-direction sliding rail in a sliding manner, the first X-direction sliding component and the second X-direction sliding component cooperate to position a detection reference of a glass lifter on the same straight line parallel to the X-direction sliding rail, a Y-direction detection structure is arranged on the second X-direction sliding component, and the relative height difference of the two sliding frames of the glass lifter is directly obtained through the Y-direction detection structure. Through setting up X to slide rail and first X to sliding member and second X to sliding member, make the detection benchmark of glass crane be located same straight line, rethread second X is to the Y on the sliding member to detecting the structure, detects the carriage for the distance on this benchmark straight line, avoids producing accumulative error.

Description

Double-guide-rail lifter sliding frame relative position detection tool

Technical Field

The utility model relates to the technical field of vehicle structures, in particular to a tool for detecting the relative position of a sliding frame of a double-guide-rail lifter.

Background

The double-guide-rail glass lifter needs to measure the distance from the first sliding frame to the bottom dead center of the guide rail and the distance from the second sliding frame to the bottom dead center of the guide rail, so that the relative height difference of the two sliding frames is obtained, and the actual track of glass is obtained.

According to the existing measuring mode, the first sliding frame and the second sliding frame are not on the same standard during measurement, so that two distances are measured by the aid of the ruler respectively, and the relative height difference is obtained by calculating the difference.

Disclosure of Invention

The utility model aims to provide a tool for detecting the relative position of a sliding frame of a double-guide-rail lifter, which avoids generating accumulated errors and directly obtains the relative height difference of two sliding frames of a glass lifter.

In order to achieve the purpose, the utility model adopts the following technical scheme.

The utility model provides a double-guide rail riser carriage relative position detects frock, includes X to slide rail, first X to sliding component and second X to sliding component, first X is connected to sliding component and second X to sliding component all slidable X is to on the slide rail, first X is to sliding component and second X to sliding component cooperate the detection benchmark location of glass riser on the same straight line parallel with X to the slide rail, be provided with Y on the second X to sliding component and detect the structure, through Y directly obtains the relative altitude difference of two balladeurs of glass riser to detecting the structure.

According to the utility model adopting the technical scheme, the first X-direction sliding component and the second X-direction sliding component are slidably connected to the X-direction sliding rails, and the width between the two sliding rails can be adjusted by sliding any sliding component so as to adapt to glass lifters with different widths; the first X-direction sliding component and the second X-direction sliding component position the glass lifter on the same straight line parallel to the X-direction sliding rail, so that the detection reference of the glass lifter is positioned on the same straight line, and then the distance of the sliding frame relative to the reference straight line is directly detected through the Y-direction detection structure on the second X-direction sliding component, namely the relative height difference of the two sliding frames of the glass lifter; the sliding distances of the two sliding frames can be prevented from being detected respectively, and accumulative errors are prevented from being generated, so that the actual track of the glass is obtained, and the detection efficiency is improved.

Preferably, the first X-direction sliding member includes a positioning block and a first X-direction slider, and the positioning block is fixedly connected to the first X-direction slider.

The positioning block is fixed on the first X-direction sliding block and moves along with the first X-direction sliding block, so that the glass lifter is suitable for positioning glass lifters with different widths.

Preferably, the positioning block is provided with a right-angle positioning part, and the right-angle positioning part abuts against the bottom of the first sliding frame of the glass lifter.

The positioning effect is improved by matching the right-angle positioning part arranged on the positioning block with the first sliding frame of the glass lifter with the rectangular bottom.

Preferably, a thread is arranged on the first X-direction sliding block, and a first locking screw penetrates through the thread to fix the first X-direction sliding block on the X-direction sliding rail.

The first X-direction sliding block is fixed on the X-direction sliding rail through the first locking screw, and the position of the first sliding block on the X-direction sliding rail can be adjusted by unscrewing the first locking screw.

Preferably, the second X-direction sliding member includes a second X-direction slider and a Y-direction detection structure formed by a Y-direction slider base and a Y-direction slider, the second X-direction slider is provided with a thread, and a second locking screw penetrates through the thread to fix the second X-direction slider on the X-direction slide rail.

The second X-direction sliding block is fixed on the X-direction sliding rail through a second locking screw, and the position of the first sliding block on the X-direction sliding rail can be adjusted by unscrewing the screw.

Preferably, the Y-direction slider base is fixedly connected to the second X-direction slider.

The Y-direction sliding block base is fixed on the second X-direction sliding block and moves along with the second X-direction sliding block to be matched with the glass lifter.

Preferably, Y is provided with the slide to the slider base on, slide and Y are to slider sliding connection, Y supports to support to the second carriage of slider and glass-frame riser and leans on, Y is provided with the scale to the slider on, through Y measures the relative altitude difference of two balladeurs framves of glass-frame riser to the scale on the slider.

And when the Y-direction sliding block moves along with the second sliding frame of the glass lifter to reach a test stop point through the graduated scale on the Y-direction sliding block, the distance measured by the graduated scale is the relative height difference of the two sliding frames of the glass lifter.

Preferably, a thread is arranged on the Y-direction slider base, and a Y-direction slider locking bolt penetrates through the thread to fix the Y-direction slider on the Y-direction slider base.

Through Y to slider locking bolt, when the second carriage removes and reaches the test dead point during the measurement, Y is to slider locking bolt locking Y to the position of slider on Y to the slider base, locks the scale position, is convenient for accurately read out the relative altitude difference of two balladeurs slidears of glass-frame riser.

Preferably, the glass lifting detection tool is further included, and the glass lifter is installed on the glass lifting detection tool through a bolt.

Through setting up glass-frame riser and examining utensil and provide the support for glass-frame riser examines utensil, be convenient for detect.

The glass lifter has the advantages that the first X-direction sliding component and the second X-direction sliding component are slidably connected to the X-direction sliding rails, and the width between the two sliding rails can be adjusted by sliding any sliding component so as to adapt to glass lifters with different widths; the first X-direction sliding component and the second X-direction sliding component position the glass lifter on the same straight line parallel to the X-direction sliding rail, so that the detection benchmarks of the first sliding frame and the second sliding frame of the glass lifter are both positioned on the same straight line, and then the distance of one sliding frame relative to the reference straight line is detected through the Y-direction sliding block and the graduated scale, namely the relative height difference of the two sliding frames of the glass lifter; the sliding distances of the two sliding frames can be prevented from being detected respectively, and accumulative errors are prevented from being generated, so that the actual track of the glass is obtained, and the detection efficiency is improved.

Drawings

FIG. 1 is a schematic diagram of the operation of the present invention;

FIG. 2 is a partial block diagram of the present invention;

FIG. 3 is an enlarged view of portion K of FIG. 2 in accordance with the present invention;

fig. 4 is an enlarged view of a portion K1 of fig. 2 according to the present invention.

Detailed Description

The present invention is further described with reference to the accompanying drawings, but the utility model is not limited thereby within the scope of the described embodiments.

Reference numerals in the drawings of the specification include: the glass lifting detection device comprises a positioning block 1, a first X-direction slider 12, an X-direction slide rail 4, a first locking screw 11, a second X-direction slider 2, a second locking screw 21, a Y-direction slider base 22, a Y-direction slider 23, a graduated scale 25, a Y-direction slider locking bolt 24, a first sliding frame 5, a second sliding frame 51 and a glass lifting detection tool 6.

Referring to fig. 1 to 2, the tool for detecting the relative position of the sliding frame of the double-guide-rail lifter comprises an X-direction sliding rail 4, a first X-direction sliding member and a second X-direction sliding member, wherein the first X-direction sliding member and the second X-direction sliding member are both slidably connected to the X-direction sliding rail 4, the first X-direction sliding member and the second X-direction sliding member cooperate to position the detection reference of the glass lifter on the same straight line parallel to the X-direction sliding rail 4, a Y-direction detection structure is arranged on the second X-direction sliding member, and the relative height difference of two sliding frames of the glass lifter is directly obtained through the Y-direction detection structure.

Referring to fig. 2 to 4, the first X-direction sliding component includes a positioning block 1 and a first X-direction slider 12, and the positioning block 1 is fixedly connected to the first X-direction slider 12.

Referring to fig. 1 and 2, the positioning block 1 is provided with a right-angle positioning portion, and the right-angle positioning portion abuts against the bottom of the first sliding frame 5 of the glass lifter. The first X-direction sliding block 12 is provided with threads, and the first locking screw 11 penetrates through the threads to fix the first X-direction sliding block 12 on the X-direction sliding rail 4.

Referring to fig. 2 to 4, the second X-direction sliding member includes a second X-direction slider 2 and a Y-direction detection structure formed by a Y-direction slider base 22 and a Y-direction slider 23, and the Y-direction slider base 22 is fixedly connected to the second X-direction slider 2.

Referring to fig. 1 and 4, a thread is arranged on the second X-direction slider 2, and a second locking screw 21 penetrates through the thread to fix the second X-direction slider 2 on the X-direction slide rail 4. The Y-direction sliding block base 22 is provided with a slide way, the slide way is connected with the Y-direction sliding block 23 in a sliding mode, and the Y-direction sliding block 23 abuts against the second sliding frame 51 of the glass lifter.

Referring to fig. 1 and 4, a graduated scale 25 is arranged on the Y-direction slider 23, and the relative height difference between the two carriages of the window regulator is measured through the graduated scale 25 on the Y-direction slider 23. The glass lifting detection tool is characterized by further comprising a glass lifting detection tool 6, and the glass lifter is installed on the glass lifting detection tool 6 through a bolt.

Referring to fig. 4, a thread is arranged on the Y-direction slider base 22, and a Y-direction slider locking bolt 24 penetrates through the thread to fix the Y-direction slider 23 on the Y-direction slider base 22.

The foregoing shows and describes the general principles and broad features of the present invention and advantages thereof. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the utility model as claimed. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (10)

1. The utility model provides a double-guide-rail lifter sliding frame relative position detects frock, its characterized in that includes X to slide rail (4), first X to sliding member and second X to sliding member, first X is connected to sliding member and second X to sliding member all slidable X is to slide rail (4) on, first X is to sliding member and second X to sliding member cooperate the detection benchmark location of glass-frame riser on the collinear with X is parallel to slide rail (4), be provided with Y on the second X to sliding member and detect the structure, through Y is to detecting the relative altitude difference that the structure directly obtained two balladers of glass-frame.

2. The tool for detecting the relative position of the double-guide-rail lifter sliding frame according to claim 1, wherein the first X-direction sliding component comprises a positioning block (1) and a first X-direction sliding block (12), and the positioning block (1) is fixedly connected to the first X-direction sliding block (12).

3. The tool for detecting the relative position of the sliding frames of the double-guide-rail lifter according to claim 2, wherein the positioning block (1) is provided with a right-angle positioning part, and the right-angle positioning part abuts against the bottom of the first sliding frame (5) of the glass lifter.

4. The tool for detecting the relative position of the double-guide-rail lifter sliding frame according to claim 2, wherein the first X-direction sliding block (12) is provided with threads, and a first locking screw (11) penetrates through the threads to fix the first X-direction sliding block (12) on the X-direction sliding rail (4).

5. The tool for detecting the relative position of the double-guide-rail lifter sliding frame according to claim 1, wherein the second X-direction sliding component comprises a second X-direction sliding block (2) and a Y-direction detection structure consisting of a Y-direction sliding block base (22) and a Y-direction sliding block (23), a thread is arranged on the second X-direction sliding block (2), and a second locking screw (21) penetrates through the thread to fix the second X-direction sliding block (2) on the X-direction sliding rail (4).

6. The tool for detecting the relative position of the double-guide-rail lifter sliding frame according to claim 5, wherein the Y-direction sliding block base (22) is fixedly connected to the second X-direction sliding block (2).

7. The tool for detecting the relative position of the sliding frame of the double-guide-rail lifter according to claim 5, wherein a slide way is arranged on the Y-direction slide block base (22), the slide way is slidably connected with the Y-direction slide block (23), and the Y-direction slide block (23) abuts against the second sliding frame (51) of the glass lifter.

8. The tool for detecting the relative position of the sliding frame of the double-guide rail lifter according to claim 7, characterized in that a graduated scale (25) is arranged on the Y-direction sliding block (23), and the relative height difference of the two sliding frames of the glass lifter is measured through the graduated scale (25).

9. The tool for detecting the relative position of the sliding frame of the double-guide-rail lifter according to claim 5, wherein a thread is arranged on the Y-direction slider base (22), and a Y-direction slider locking bolt (24) penetrates through the thread to fix the Y-direction slider (23) on the Y-direction slider base (22).

10. The tool for detecting the relative position of the double-guide-rail lifter sliding frame according to claim 1, further comprising a glass lifting detection tool (6), wherein the glass lifter is mounted on the glass lifting detection tool (6) through a bolt.

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