CN217403385U - Glass tube diameter detection device - Google Patents

Abstract

The utility model relates to a medicinal glass manages the detection area, discloses glass manages diameter detection device, including main part (1), be equipped with on main part (1) and be used for the installation fixed subassembly (3) of glass pipe (5) and be used for detecting detection subassembly (2) of glass pipe (5) diameter install extremely fixed subassembly (3) glass pipe (5) with can along between detection subassembly (2) the length direction relative movement of glass pipe (5), so that detection subassembly (2) can detect out the diameter of glass pipe (5) different positions on its length direction. Through above-mentioned technical scheme, glass pipe and determine module can relative movement to make determine module can detect the diameter of glass pipe optional position on length direction, this detection device operation is high-efficient, stable, and measurement accuracy is high, and the testing process reduces the staff and drops into, reduces the cost of labor.

Description

Glass tube diameter detection device

Technical Field

The utility model relates to a medicinal glass manages the check out test set field, specifically relates to a glass manages diameter detection device.

Background

The diameter detection of the medicinal glass tube is an unnecessary link in quality control. Detecting separation line and on-line. The off-line detection plays an important role in product batch sampling inspection and mutual verification of measurement systems because the measurement is more stable and accurate.

Therefore, the main problems of the conventional detection technology are that the efficiency is low, the accuracy is poor, and under the condition that the number of detected samples is large, more manpower and time are required to be invested.

SUMMERY OF THE UTILITY MODEL

The utility model aims at overcoming the relatively low problem of detection efficiency, the degree of accuracy that prior art exists, providing a glass pipe diameter detection device, the device has the characteristics of the operation high efficiency, stable, low in production cost.

In order to achieve the above object, an aspect of the present invention provides a glass tube diameter detecting device, which comprises a main body, wherein the main body is provided with a fixing component for installing the glass tube and a detecting component for detecting the diameter of the glass tube, and the fixing component is installed on the glass tube and the detecting component can move along the length direction of the glass tube, so that the detecting component can detect out the diameters of different positions of the glass tube in the length direction.

Optionally, the glass tube fixing device further comprises a sliding assembly arranged on the main body, and the fixing assembly can move along the length direction of the glass tube through the sliding assembly.

Optionally, the sliding assembly comprises a guide rail extending along the length of the glass tube, and the fixing assembly is in sliding fit with the guide rail.

Optionally, the sliding assembly further comprises a sliding block slidably disposed on the guide rail, and the fixing assembly is disposed on the sliding block.

Optionally, the number of the fixed assemblies is multiple, two of the fixed assemblies are respectively connected with two ends of the glass tube, the number of the sliding blocks is the same as that of the fixed assemblies, and one fixed assembly is arranged on each sliding block.

Optionally, the fixing device further comprises a driving assembly arranged on the main body, and the driving assembly is used for driving the fixing assembly to move along the length direction of the guide rail.

Optionally, the driving assembly includes a driver, a first synchronous pulley disposed on the main shaft of the driver, a second synchronous pulley horizontally spaced from the first synchronous pulley, and a synchronous belt for connecting the first synchronous pulley and the second synchronous pulley, and the fixing assembly is driven to move by rotation of the synchronous belt.

Optionally, a connecting rod is arranged between two adjacent sliding blocks, and the synchronous belt is connected with the sliding blocks through connecting pieces to drive the sliding blocks to move synchronously.

Optionally, the fixing assembly comprises a supporting base for supporting the glass tube and a flip cover hinged to the supporting base.

Optionally, the detection assembly comprises an emitting piece and a receiving piece which are oppositely arranged at two sides of the glass tube, and the emitting piece and the receiving piece are respectively arranged on the main body through brackets.

Through above-mentioned technical scheme, glass pipe and determine module can relative movement to make determine module can detect the diameter of glass pipe optional position on length direction, this detection device operation is high-efficient, stable, and measurement accuracy is high, and the testing process reduces the staff and drops into, reduces the cost of labor.

Drawings

FIG. 1 is a schematic structural view of an embodiment of a glass tube diameter detecting device according to the present invention;

FIG. 2 is a schematic structural view of one embodiment of a securing assembly of the present invention;

FIG. 3 is a schematic structural view of one embodiment of a slide assembly of the present invention;

fig. 4 is a schematic structural diagram of an embodiment of the driving assembly of the present invention.

Description of the reference numerals

1-a main body, 2-a detection component, 3-a fixed component, 4-a sliding component, 5-a glass tube, 6-a driving component, 7-a connecting piece, 21-a support, 31-a supporting seat, 32-a turnover cover, 33-a fixed plate, 41-a sliding block, 42-a guide rail, 43-a connecting rod, 61-a driver, 62-a first synchronous pulley, 63-a second synchronous pulley, 64-a synchronous belt, 65-a first fixed seat and 66-a second fixed seat.

Detailed Description

The following detailed description of the embodiments of the present invention will be made with reference to the accompanying drawings. It is to be understood that the description of the embodiments herein is for purposes of illustration and explanation only and is not intended to limit the invention.

The utility model discloses a glass manages diameter detection device, including main part 1, be equipped with the fixed subassembly 3 that is used for installing glass pipe 5 and the determine module 2 that is used for detecting glass pipe 5 diameter on main part 1, install to can be along glass pipe 5's length direction relative movement between fixed subassembly 3's glass pipe 5 and the determine module 2 to make determine module 2 can detect out the diameter of glass pipe 5 different positions on its length direction.

As shown in fig. 1, the fixing component 3 and the detecting component 2 are disposed on the main body 1, the glass tube 5 can be mounted on the fixing component 3 and can move relative to the detecting component 2, that is, the detecting component 2 can continuously measure the diameter of the glass tube 5 in the moving process, and then determine whether the glass tube 5 is qualified or not according to the measured result.

Through above-mentioned technical scheme, glass pipe and determine module can relative movement to make determine module can detect the diameter of glass pipe optional position on length direction, this detection device operation is high-efficient, stable, and measurement accuracy is high.

Further, as shown in fig. 1, the detecting device further includes a sliding member 4 provided on the main body 1, and the fixing member 3 is movable in a length direction of the glass tube 5 by the sliding member 4.

As an implementation mode, in the application, the detection component 2 is fixedly arranged on the main body 1, the fixed component 3 is arranged on the main body 1 in a sliding mode, relative movement of the detection component and the fixed component is achieved, the sliding component 4 provides guidance for sliding of the fixed component 3, the guiding direction of the guidance is consistent with the length direction of the glass tube 5, and measured data are more accurate in the moving process of the glass tube 5.

Wherein the sliding assembly 4 includes a guide rail 42 extending along a length direction of the glass tube 5, and the fixing assembly 3 is slidably engaged with the guide rail 42.

As shown in fig. 1 and 3, the guide rail 42 is provided on the main body 1, and the fixing member 3 is slidably provided on the guide rail 42, and the extending direction of the guide rail 42 is the same as the longitudinal direction of the glass tube 5 mounted on the fixing member 3.

Further, the sliding assembly 4 further includes a sliding block 41 slidably disposed on the guide rail 42, and the fixing assembly 3 is disposed on the sliding block 41.

As shown in fig. 1 and 3, the fixing assembly 3 can slide on the guide rail 42 more smoothly and stably by the arrangement of the sliding block 41, so that the glass tube 5 is more convenient and stable in the measuring process, the measuring result is more accurate, and the measuring operation by the operator is more convenient.

Wherein, the quantity of fixed subassembly 3 is a plurality of, and wherein two fixed subassemblies 3 are connected with the both ends of glass pipe 5 respectively, and the quantity of slider 41 is the same with the quantity of fixed subassembly 3, is equipped with a fixed subassembly on every slider 41.

Referring to fig. 1 and 3, in order to ensure that the glass tube 5 is mounted on the fixing assembly 3 without shaking, sliding, and the like, three fixing assemblies 3 are selected, two of the fixing assemblies are respectively connected with two ends of the glass tube 5, the other fixing assembly is connected with the middle position of the glass tube 5, and correspondingly, three sliding blocks 41 are also provided.

As other alternative embodiments, the number of the fixing assemblies 3 may also be one, and then the length of the fixing assemblies 3 is long enough to enable the fixing assemblies 3 to have a better supporting effect on the glass tube 5, so as to ensure that the glass tube 5 can be more stable after being installed.

Further, the detection device further comprises a driving assembly 6 disposed on the main body 1, wherein the driving assembly 6 is used for driving the fixing assembly 3 to move along the length direction of the guide rail 42.

As an embodiment, the fixing component 3 can also be fixedly disposed on the main body 1, in which case the detecting component 2 is slidably disposed on the main body 1, so that the detecting component 2 and the fixing component 3 can move relatively. It can be seen that the arrangement of the fixing component 3 and the detecting component 2 is not limited, as long as the fixing component 3 and the detecting component 2 can be moved relatively, and the diameters of the glass tube 5 on the fixing component 3 at different positions in the length direction can be detected by the detecting component 2 during the moving process.

As shown in figure 1, can drive fixed subassembly 3 through drive assembly 6 and remove, can make the removal of glass pipe 5 more stable, speed more even, increased measuring accuracy, automatic setting can effectively reduce operating personnel's work load simultaneously, makes to detect more convenient, swift.

The driving assembly 6 comprises a driver 61, a first synchronous pulley 62 arranged on the main shaft of the driver 61, a second synchronous pulley 63 horizontally spaced from the first synchronous pulley 62, and a synchronous belt 64 for connecting the first synchronous pulley 62 and the second synchronous pulley 63, and the fixing assembly 3 is driven to move by the rotation of the synchronous belt 64.

As shown in fig. 4, the driver 61 drives the first synchronous pulley 62 on the main shaft to rotate, the second synchronous pulley 63 is used as a driven pulley, the synchronous belt 64 rotates between the first synchronous pulley 62 and the second synchronous pulley 63 under the driving action of the first synchronous pulley 62, and the fixing assembly 3 is driven to move back and forth in the extending direction of the guide rail 42 by the clockwise and counterclockwise rotation of the synchronous belt 64. The driver 61 can select a stepping motor, a servo motor and other driving members, and in this application, the micro servo motor is used for driving to perform uniform motion.

Further, as shown in fig. 1 and 4, the driver 61 is disposed on the main body 1 through a first fixing seat 65, the second synchronous pulley 63 is disposed on the main body 1 through a second fixing seat 66, and the extending directions of the first fixing seat 65 and the second fixing seat 66 are parallel to the extending direction of the guide rail 42, so as to ensure that the slider 41 can move stably.

In one embodiment, a connecting rod 43 is disposed between two adjacent sliding blocks 41, and a timing belt 64 is connected to the sliding blocks 41 through a connecting member 7 to drive the sliding blocks 41 to move synchronously.

As shown in fig. 3, the three sliding blocks 41 can be driven to move synchronously by connecting the sliding blocks 41 into a whole through the connecting rod 43; in order to make the movement of the sliding blocks 41 smoother, the connecting members 7 are disposed at the middle positions of the sliding blocks 41, that is, the connecting members 7 are disposed on the middle sliding blocks 41, the connecting members 7 may be disposed on the sliding blocks 41 at both ends, or each sliding block 41 may be provided with the connecting members 7.

Further, the fixing assembly 3 includes a supporting base 31 for supporting the glass tube 5 and a flip cover 32 hinged on the supporting base 31.

As shown in fig. 2, the supporting seat 31 is provided with a groove, when the glass tube 5 is mounted, the glass tube 5 is placed in the groove of the supporting seat 31, and the flip cover 32 is closed to clamp the glass tube 5, so as to prevent the glass tube 5 from sliding or falling off during movement.

Wherein, the fixing component 3 further comprises a fixing plate 33, as shown in fig. 2, the supporting seat 31 is disposed on the fixing plate 33, the fixing component 3 is disposed on the sliding block 41 through the fixing plate 33, and the connecting member 7 is also disposed on the sliding block 41 through the fixing plate 33.

As an embodiment, the detecting assembly 2 includes an emitting element and a receiving element oppositely disposed at both sides of the glass tube 5, and the emitting element and the receiving element are respectively disposed on the main body 1 through the brackets 21.

As shown in FIG. 1, the laser signal path between the emitting piece and the receiving piece is perpendicular to the length direction of the glass tube 5, and the detecting assembly 2 should be placed at the middle position of the main body 1, so that the detecting assembly 2 can measure and detect both ends of the glass tube 5. Wherein the detection module consists of a laser measuring unit, a transmitter and a receiver, and the height of the detection component 2 is adjusted by the bracket 21 to be flush with the height of the glass tube 5.

The preferred embodiments of the present invention have been described in detail with reference to the accompanying drawings, but the present invention is not limited thereto. In the technical idea scope of the present invention, it can be right to the technical solution of the present invention carry out multiple simple variants, these simple variants and combinations should be regarded as the disclosed content of the present invention, all belong to the protection scope of the present invention.

It should be noted that the various features described in the above embodiments may be combined in any suitable manner without departing from the scope of the invention. In order to avoid unnecessary repetition, the present invention does not separately describe various possible combinations.

In addition, various embodiments of the present invention can be combined arbitrarily, and the disclosed content should be regarded as the present invention as long as it does not violate the idea of the present invention.

Claims (10)

1. The glass tube diameter detection device is characterized by comprising a main body (1), wherein the main body (1) is provided with a fixing component (3) for installing a glass tube (5) and a detection component (2) for detecting the diameter of the glass tube (5), and the glass tube (5) and the detection component (2) are installed on the fixing component (3) and can move relatively along the length direction of the glass tube (5) between the detection component (2), so that the detection component (2) can detect the diameters of the glass tube (5) at different positions in the length direction.

2. The glass tube diameter detecting device according to claim 1, further comprising a sliding assembly (4) provided on the main body (1), wherein the fixing assembly (3) is movable in a length direction of the glass tube (5) by the sliding assembly (4).

3. The glass tube diameter detecting device according to claim 2, wherein the sliding assembly (4) includes a guide rail (42) extending along a length direction of the glass tube (5), and the fixing assembly (3) is slidably fitted to the guide rail (42).

4. The glass tube diameter detection device according to claim 3, wherein the sliding assembly (4) further comprises a sliding block (41) slidably disposed on the guide rail (42), and the fixing assembly (3) is disposed on the sliding block (41).

5. The glass tube diameter detection device according to claim 4, characterized in that the number of the fixing assemblies (3) is plural, two of the fixing assemblies (3) are respectively connected with two ends of the glass tube (5), the number of the sliding blocks (41) is the same as that of the fixing assemblies (3), and one fixing assembly is arranged on each sliding block (41).

6. The glass tube diameter detection device according to claim 4, further comprising a driving assembly (6) disposed on the main body (1), wherein the driving assembly (6) is used for driving the fixing assembly (3) to move along the length direction of the guide rail (42).

7. The glass tube diameter detecting device according to claim 6, wherein the driving assembly (6) includes a driver (61), a first timing pulley (62) provided on a main shaft of the driver (61), a second timing pulley (63) horizontally spaced from the first timing pulley (62), and a timing belt (64) for connecting the first timing pulley (62) and the second timing pulley (63), the fixed assembly (3) being driven to move by rotation of the timing belt (64).

8. The glass tube diameter detecting device according to claim 7, wherein a connecting rod (43) is arranged between two adjacent sliding blocks (41), and the synchronous belt (64) is connected with the sliding blocks (41) through a connecting piece (7) to drive the sliding blocks (41) to move synchronously.

9. The glass tube diameter detecting device according to any one of claims 1 to 8, wherein the fixing member (3) comprises a support base (31) for supporting the glass tube (5) and a lid (32) hinged to the support base (31).

10. The glass tube diameter detecting device according to any one of claims 1 to 8, wherein the detecting assembly (2) includes an emitting piece and a receiving piece which are oppositely disposed at both sides of the glass tube (5), and the emitting piece and the receiving piece are respectively disposed on the main body (1) through brackets (21).

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