CN219117339U - Medical glass flake sample cutting machine - Google Patents

Abstract

The utility model belongs to the technical field of glass cutting equipment, and particularly relates to a medical glass sheet sample cutting machine which comprises a glass slide, wherein a glass pushing mechanism is arranged in the glass slide, a liftable cutter is arranged at the tail end of the glass slide, and the length of the cutter is matched with the width of the glass slide. The method comprises the steps of placing a large glass flake sample in a glass slideway, under the action of a glass pushing mechanism, continuously advancing the glass flake sample along the glass slideway, rapidly descending a cutter at the tail end of the glass slideway, and directly cutting off the large glass flake sample to form a small sample under the action of the impact force and sharp cutting edge of the cutter due to the fact that the sample is thinner, so that the small sample is used for analysis experiments. The glass sheet cutting device is different from a common glass cutting mode in terms of the characteristics of the glass sheet, and through reasonable structural design, the cutting efficiency is improved while the cutting integrity of a glass sheet sample is ensured, the manual cutting is replaced, the labor intensity of workers is reduced, and the automation degree of a workshop is improved.

Description

Medical glass flake sample cutting machine

Technical Field

The utility model relates to a medicinal glass flake sample cutting machine, and belongs to the technical field of glass cutting equipment.

Background

The medicinal glass is glass for medicine packaging, generally refers to glass bottles and vessels, and the glass thickness is generally thinner. Because the medical glass needs to take quantitative samples for analysis experiments, and the arc-shaped glass bottle structure is difficult to adapt to corresponding instruments, generally, each batch of medical glass needs to be prepared into an independent glass sheet sample, and the prepared glass sheet sample needs to be divided into a block of small samples with basically equal area, and a block of large sample glass is cut.

However, the glass cutter in the prior art is a special processing machine for processing and blanking common glass, such as a glass cutter for processing a computer touch pad with the application number of CN201920012993.2, or a glass cutter cutting head mechanism with the application number of CN200520066708.3, which adopts a rotary cutting tool, and the cutting structure is only suitable for common thicker glass cutting, and the conventional cutting tool is difficult to cut due to the thicker and high hardness of common glass; however, the rotating cutting tool can generate larger vibration in the working process, if the rotating cutting tool is used for cutting the glass sheet, the vibration can directly shake the sheet into pieces, and a complete sheet sample is difficult to form.

Although the integrity of the sample can be ensured by manual cutting, the manual cutting efficiency is low, the glass is sharp, and the working has a certain danger. The present cutter is specifically designed in view of the nature of the glass sheet, intended to make small, fractional cuts of the glass sheet.

Disclosure of Invention

According to the defects in the prior art, the technical problems to be solved by the utility model are as follows: the utility model provides a medicinal glass flake sample cutting machine, when guaranteeing cutting integrality, promotes cutting efficiency.

The utility model relates to a medicinal glass sheet sample cutting machine, which comprises a glass slide way, wherein a glass pushing mechanism is arranged in the glass slide way, a liftable cutting knife is arranged at the tail end of the glass slide way, and the length of the cutting knife is matched with the width of the glass slide way.

The method comprises the steps of placing a large glass flake sample in a glass slideway, under the action of a glass pushing mechanism, continuously advancing the glass flake sample along the glass slideway, rapidly descending a cutter at the tail end of the glass slideway, and directly cutting off the large glass flake sample to form a small sample under the action of the impact force and sharp cutting edge of the cutter due to the fact that the sample is thinner, so that the small sample is used for analysis experiments.

The glass pushing mechanism comprises a push plate positioned in the glass slide way, and the push plate is fixed on a sliding block which can slide along the miniature linear guide rail.

Further, the sliding block is driven by a gear rack mechanism to reciprocate.

The utility model discloses a miniature linear guide rail, wherein travel switches are arranged at two ends of the miniature linear guide rail and are used for controlling the travel of a sliding block and limiting protection.

The two ends of the miniature linear guide rail are provided with the straight stop blocks, so that the physical limit of the sliding block is realized.

In the utility model, the cutter is arranged on the sliding seat of the magnetic coupling rodless cylinder, and is driven by the magnetic coupling rodless cylinder to perform lifting action.

According to the utility model, the tail end of the glass slide rail is of a stepped structure, so that a staggered platform is formed, and the glass slide rail can be matched with a cutter to better realize cutting of glass sheets.

Compared with the prior art, the utility model has the following beneficial effects:

the medical glass flake sample cutting machine provided by the utility model is different from a common glass cutting mode in terms of the characteristics of glass flakes, and has the advantages that the cutting efficiency is improved while the cutting integrity of the glass flake sample is ensured, the manual cutting is replaced, the labor intensity of workers is reduced, and the automation degree of workshops is improved through reasonable structural design.

Drawings

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

FIG. 2 is one of the schematic diagrams of the course of action of the present utility model;

FIG. 3 is a second schematic diagram of the operation process of the present utility model;

FIG. 4 is an enlarged view of a portion of the portion A of FIG. 3;

fig. 5 is a schematic perspective view of the back side of the present utility model.

In the figure: a fixing plate 1; a micro linear guide rail 2; a slider 3; a push plate 4; a mounting frame 5; a servo motor 6; a travel switch 7; a glass slide 8; glass flake sample 9; a sample carrier plate 10; a cutter 11; a magnetic coupling rodless cylinder 12; cut sample 13; a pinion 14; a rack 15.

Detailed Description

The utility model will be further illustrated with reference to specific examples.

However, the description of the present utility model is merely an embodiment of a structural or even functional description, and the scope of the claims of the present utility model is not limited by the embodiments described herein.

For example, the embodiments may have various modifications and various forms, and it is to be understood that the scope of the claims of the present utility model includes equivalents capable of realizing the technical idea.

Also, since the objects or effects achieved by the present utility model do not mean that a specific embodiment should include all or only those effects, the scope of the right of the present utility model is not limited thereby.

As shown in fig. 1 to 5, the medical glass flake sample cutting machine according to the embodiment comprises a fixed plate 1, a micro linear guide rail 2 is arranged on the fixed plate 1, a sliding block 3 capable of sliding along the length direction of the micro linear guide rail 2 is arranged on the micro linear guide rail 2, and the sliding block 3 is driven by a gear rack mechanism to reciprocate.

The rack 15 of the gear-rack mechanism is positioned at the back of the fixed plate 1, a pinion 14 meshed with the rack 15 is arranged on the output shaft of the servo motor 6, and the servo motor 6 is fixedly arranged with the sliding block 3 through the mounting frame 5.

The push plate 4 is fixed on the slide block 3 and moves along with the slide block 3, the bottom of the push plate 4 is basically contacted with the upper plane of the glass slide way 8, and the tail end of the glass slide way 8 is of a stepped structure. A liftable cutter 11 is arranged above the tail end of the glass slide 8, and the length of the cutter 11 is matched with the width of the glass slide 8. The cutter 11 is arranged on a sliding seat of the magnetic coupling rodless cylinder 12, the magnetic coupling rodless cylinder 12 is driven by the magnetic coupling rodless cylinder 12 to perform lifting action, and the magnetic coupling rodless cylinder 12 is arranged between the fixed plate 1 and the sample bearing plate 10.

The two ends of the miniature linear guide rail 2 are provided with a travel switch 7 and a straight stop block for controlling the travel of the sliding block and limiting protection.

For ease of understanding, the working procedure of this embodiment is given below:

the large glass flake sample 9 is placed in the glass slideway 8, the servo motor 6 drives the sliding block 3 and the pushing plate 4 to move through the gear rack mechanism, the glass flake sample 9 continuously advances along the glass slideway 8, the magnetic coupling rodless cylinder 12 acts at the tail end of the glass slideway 8, the cutter 11 rapidly descends, the large glass flake sample 9 is directly cut off to form a small sample under the impact force and sharp blade action of the cutter 11 due to the thinner sample, and the cut sample 13 falls on the sample bearing plate 10 for later analysis experiments.

Of course, the foregoing is merely preferred embodiments of the present utility model and is not to be construed as limiting the scope of the embodiments of the present utility model. The present utility model is not limited to the above examples, and those skilled in the art will appreciate that the present utility model is capable of equally varying and improving within the spirit and scope of the present utility model.

Claims (7)

1. A medical glass flake sample cutting machine, which is characterized in that: the glass slide comprises a glass slide (8), a glass pushing mechanism is arranged in the glass slide (8), a liftable cutting knife (11) is arranged at the tail end of the glass slide (8), and the length of the cutting knife (11) is matched with the width of the glass slide (8).

2. The pharmaceutical glass flake sample cutting machine of claim 1, wherein: the glass pushing mechanism comprises a push plate (4) positioned in a glass slideway (8), and the push plate (4) is fixed on a sliding block (3) which can slide along the miniature linear guide rail (2).

3. The pharmaceutical glass flake sample cutting machine of claim 2, wherein: the sliding block (3) is driven by a gear-rack mechanism to reciprocate.

4. A pharmaceutical glass flake sample cutter as defined in claim 3 wherein: and travel switches (7) are arranged at two ends of the miniature linear guide rail (2).

5. A pharmaceutical glass flake sample cutter as defined in claim 3 wherein: the two ends of the miniature linear guide rail (2) are provided with straight stop blocks.

6. The pharmaceutical glass flake sample cutting machine of claim 1, wherein: the cutting knife (11) is arranged on a sliding seat of the magnetic coupling rodless cylinder (12), and is driven by the magnetic coupling rodless cylinder (12) to perform lifting action.

7. The pharmaceutical glass flake sample cutting machine of claim 1, wherein: the tail end of the glass slide way (8) is of a stepped structure.

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