CN219607957U - Substrate glass height measuring device - Google Patents

Abstract

The utility model discloses a substrate glass height measurement device, which comprises a distance changing frame assembly, wherein a height measurement telescopic arm assembly is arranged on the distance changing frame assembly, the height measurement telescopic arm assembly forms a self-folding substrate glass height measurement arm structure on the distance changing frame assembly.

Description

Substrate glass height measuring device

Technical Field

The utility model belongs to the technical field of substrate glass, and particularly relates to a substrate glass height measuring device.

Background

In glass production, a substrate glass is drawn down to an annealing furnace by overflow, the glass is drawn to transverse cutting by rotation of rollers, and then the substrate is broken by a breaking robot and sent to a conveyor process.

The prior art has the following problems: during the production process, through the collection and analysis of the data, we find that the glass powder generated by breaking the substrate has correlation with the height of the substrate. In general, the measurement mode of the plate height is that line staff collects artificial ear materials, the plate height is measured through manual visual observation of a straight tape measure, time and labor are consumed in the mode, and measurement accuracy cannot be guaranteed.

Disclosure of Invention

To solve the problems set forth in the background art. The utility model provides a substrate glass height measuring device which has the characteristic of convenient use.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the substrate glass height measurement device comprises a distance changing frame assembly, wherein a height measurement telescopic arm assembly is arranged on the distance changing frame assembly, and the height measurement telescopic arm assembly forms a self-folding substrate glass height measurement arm structure on the distance changing frame assembly;

the variable-pitch frame assembly comprises a U-shaped variable-pitch frame, a main sliding rod and sliding grooves are arranged on the U-shaped variable-pitch frame, two ends of the main sliding rod are provided with a perforated sliding block in a sliding mode, the top of the perforated sliding block is fixedly provided with a toothed moving plate through a guide convex sliding rod, the top of the U-shaped variable-pitch frame is fixedly provided with a top frame and a handle, a rotating gear and a rotating handle are arranged on the top frame in a rotating mode, and a jacking spring is sleeved on the main sliding rod.

Preferably, the height measurement telescopic arm assembly comprises a height measurement telescopic arm, end pillow blocks are arranged at two ends of the height measurement telescopic arm, and a laser range finder and a rubber baffle are arranged on the end pillow blocks.

Preferably, both ends of the height measurement telescopic arm are in a closed structure, and both ends of the middle arm body of the height measurement telescopic arm are rotationally connected with the two perforated sliding blocks through shaft pins.

Preferably, the two perforated sliders synchronously approach or depart from the two ends of the main sliding rod, and the two ends of the jacking spring respectively abut against the two perforated sliders.

Preferably, the two toothed plates at the tops of the two perforated sliding blocks are respectively meshed with the two side tooth bodies of the rotating gear.

Preferably, the guide convex slide bar slides reciprocally in the slide groove, and the two slide blocks with holes naturally displace towards the two ends of the main slide bar through the pushing of the pushing spring.

Compared with the prior art, the utility model has the beneficial effects that: when the telescopic arm is used, the two ends of the middle arm body of the height measurement telescopic arm are rotationally connected with the two perforated sliding blocks through the shaft pins, at the moment, the two ends of the jacking springs are respectively abutted against the two perforated sliding blocks, the tops of the perforated sliding blocks are fixedly provided with the toothed moving plates through the guide convex sliding rods, at the moment, the two toothed moving plates at the tops of the two perforated sliding blocks are respectively meshed with the toothed bodies at the two sides of the rotating gear, in actual use, the two perforated sliding blocks naturally displace towards the two ends of the main sliding rod through the jacking springs, at the moment, the two perforated sliding blocks are in a far away structure, at the moment, the height measurement telescopic arm is in a furling clamping structure, at the moment, in actual use, the two ends of the height measurement telescopic arm are respectively provided with the end pillow blocks, the end pillow blocks are provided with the laser range finder and the rubber baffle plate, the two end pillow blocks are respectively used as a mounting table and a target table of the laser range finder, the laser range finder and the target table are opposite to each other, at the moment, in actual use, at the moment, the two toothed moving plates at the tops of the two perforated sliding blocks are respectively meshed with the toothed bodies at the two sides of the rotating gear, at the moment, the two ends of the glass substrate are respectively, in actual use, the height is measured, and the two telescopic arms are in the opposite directions, and the two telescopic structures are in the directions, and the two telescopic structures can be opened through the two telescopic structures, and the telescopic arm can be conveniently and can be unfolded through the two telescopic structures.

Drawings

FIG. 1 is a perspective view of the present utility model;

FIG. 2 is an exploded view of the present utility model;

FIG. 3 is a perspective view of a spacer assembly of the present utility model;

FIG. 4 is an exploded view of the spacer assembly of the present utility model;

FIG. 5 is a perspective view of the height finding telescoping arm assembly of the present utility model;

in the figure: 100. a range frame assembly; 101. a U-shaped variable-pitch frame; 102. a main slide bar; 103. a chute; 104. a spring is tightly propped; 105. a handle; 106. a top frame; 107. rotating the gear; 108. rotating the handle; 109. a perforated slider; 110. guiding the convex slide bar; 111. a tooth moving plate; 200. height measurement telescopic arm assembly; 201. height measurement telescopic arms; 202. an end pillow block; 203. a laser range finder; 204. a rubber baffle.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-5, the present utility model provides the following technical solutions: the substrate glass height measurement device comprises a distance changing frame assembly 100, wherein a height measurement telescopic arm assembly 200 is arranged on the distance changing frame assembly 100, and the height measurement telescopic arm assembly 200 forms a self-folding substrate glass height measurement arm structure on the distance changing frame assembly 100;

the pitch-changing frame assembly 100 comprises a U-shaped pitch-changing frame 101, a main sliding rod 102 and a sliding chute 103 are arranged on the U-shaped pitch-changing frame 101, two ends of the main sliding rod 102 are provided with a perforated sliding block 109 in a sliding mode, the top of the perforated sliding block 109 is fixedly provided with a tooth moving plate 111 through a guide convex sliding rod 110, the top of the U-shaped pitch-changing frame 101 is fixedly provided with a top frame 106 and a handle 105, the top frame 106 is rotatably provided with a rotating gear 107 and a rotating handle 108, and the main sliding rod 102 is sleeved with a jacking spring 104.

In this embodiment, preferably, the height measurement telescopic arm assembly 200 includes a height measurement telescopic arm 201, two ends of the height measurement telescopic arm 201 are provided with end pillow blocks 202, and the end pillow blocks 202 are provided with a laser range finder 203 and a rubber baffle 204.

In this embodiment, preferably, both ends of the height-measuring telescopic arm 201 are in a closed structure, and both ends of the middle arm body of the height-measuring telescopic arm 201 are rotatably connected with the two perforated sliders 109 through shaft pins.

In this embodiment, preferably, the two perforated sliders 109 move closer to or away from each other at both ends of the main slide 102, and both ends of the jack spring 104 abut against the two perforated sliders 109, respectively.

In this embodiment, preferably, two toothed plates 111 on top of two perforated sliders 109 are respectively engaged with two side teeth of the rotating gear 107.

In this embodiment, preferably, the guiding convex slide bar 110 slides reciprocally in the slide groove 103, and the two slide blocks 109 with holes naturally displace toward the two ends of the main slide bar 102 by pushing the pushing spring 104.

The working principle and the using flow of the utility model are as follows: when the height-measuring telescopic arm is used, the two ends of the arm body in the middle of the height-measuring telescopic arm 201 are rotationally connected with two perforated slide blocks 109 through shaft pins, at the moment, the two ends of the jacking spring 104 are respectively abutted against the two perforated slide blocks 109, the tops of the perforated slide blocks 109 are fixedly provided with tooth moving plates 111 through guide convex sliding rods 110, at the moment, the two tooth moving plates 111 at the tops of the two perforated slide blocks 109 are respectively meshed with the two tooth bodies of the rotating gear 107, in actual use, the two perforated slide blocks 109 naturally displace towards the two ends of the main sliding rod 102 through the pushing of the jacking spring 104, at the moment, the two perforated slide blocks 109 are in a far-away structure, at the moment, the height-measuring telescopic arm 201 is in a furling clamping structure, in actual use, the two ends of the height-measuring telescopic arm 201 are provided with end shaft blocks 202, the end pillow block 202 is provided with the laser range finder 203 and the rubber baffle 204, the two end pillow blocks 202 are respectively used as an installation table and a target table of the laser range finder 203, the laser range finder is opposite to the target table, the height of the glass substrate is measured through the laser range finder and the target table, and meanwhile, in actual use, as the two toothed plates 111 at the tops of the two perforated sliding blocks 109 are respectively meshed with two side toothed bodies of the rotating gear 107, the rotating handle 108 is rotated to reversely rotate the gear 107, the two perforated sliding blocks 109 are in a close structure, the height measuring telescopic arm 201 is in an abduction structure, and the opening of the arm display is realized through the structure, so that the glass substrates with different heights can be measured conveniently.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. A substrate glass height measurement device comprising a spacer assembly (100), characterized in that: the height measurement telescopic arm assembly (200) is arranged on the distance-changing frame assembly (100), and the height measurement telescopic arm assembly (200) forms a self-folding substrate glass height measurement arm structure on the distance-changing frame assembly (100);

the variable-pitch frame assembly (100) comprises a U-shaped variable-pitch frame (101), a main sliding rod (102) and a sliding groove (103) are arranged on the U-shaped variable-pitch frame (101), a perforated sliding block (109) is arranged at two ends of the main sliding rod (102) in a sliding mode, a tooth moving plate (111) is fixedly arranged at the top of the perforated sliding block (109) through a guide convex sliding rod (110), a top frame (106) and a handle (105) are fixedly arranged at the top of the U-shaped variable-pitch frame (101), a rotating gear (107) and a rotating handle (108) are rotatably arranged on the top frame (106), and a jacking spring (104) is sleeved on the main sliding rod (102).

2. The substrate glass height measurement device according to claim 1, wherein: the height measurement telescopic arm assembly (200) comprises a height measurement telescopic arm (201), end pillow blocks (202) are arranged at two ends of the height measurement telescopic arm (201), and a laser range finder (203) and a rubber baffle (204) are arranged on the end pillow blocks (202).

3. The substrate glass height measurement device according to claim 2, wherein: the two ends of the height measurement telescopic arm (201) are both arranged to be of a closed structure, and the two ends of the middle arm body of the height measurement telescopic arm (201) are both rotationally connected with the two perforated sliding blocks (109) through shaft pins.

4. The substrate glass height measurement device according to claim 1, wherein: the two perforated sliding blocks (109) synchronously approach or separate from the two ends of the main sliding rod (102), and the two ends of the jacking spring (104) are respectively abutted against the two perforated sliding blocks (109).

5. The substrate glass height measurement device according to claim 1, wherein: two tooth moving plates (111) at the tops of the two perforated sliding blocks (109) are respectively meshed with two side tooth bodies of the rotating gear (107).

6. The substrate glass height measurement device according to claim 1, wherein: the guide convex slide bar (110) slides back and forth in the slide groove (103), and the two slide blocks (109) with holes naturally displace towards the two ends of the main slide bar (102) through pushing of the pushing spring (104).