CN211452700U - Automatic center correcting device for screw cap - Google Patents

Abstract

The utility model relates to a spiral cover automatic torsion test used device field, in particular to spiral cover automatic correction center's device. The automatic correction center device of the screw cap mainly comprises a fixing device, wherein the automatic correction center device of the screw cap comprises a horizontal fixing plate, an X-axis fixing plate, an X-direction optical axis, an XY-axis connecting plate, a Y-axis fixing plate, a Y-direction optical axis, a sensor fixing plate, a measuring head fixing plate, a torsion sensor, an upper clamp clamping cylinder and an upper clamp; the utility model discloses spiral cover automatic correction center device sample can not incline, and measured value and actual value are more accurate, more high-efficient, also can greatly reduced instrument test error for measured data is more accurate, and work efficiency improves greatly, uses convenient and fast more.

Description

Automatic center correcting device for screw cap

Technical Field

The utility model relates to a spiral cover automatic torsion test used device field, in particular to spiral cover automatic correction center's device.

Background

The existing automatic torque force testing clamping device tool mainly clamps a bottle cap and a bottle body respectively, then applies radial torque force to a sample to be tested by using an upper clamp or a lower clamp, and accurately measures the screwing force and the opening force between the bottle cap and the bottle body through a sensor.

The utility model discloses spiral cover automatic correction central installation is through about direction (X axle), the optical axis of front and back direction (Y axle) use the high accuracy to connect for the horizontal direction, because the optical axis frictional force of high accuracy is little, toughness is good, various aspects advantages such as intensity height, go up anchor clamps and when anchor clamps are not on same vertical direction (Z axle) axis down, anchor clamps autogiration down, Z axle torsion does not receive any influence, it can pass through the X axle to go up anchor clamps, Y axle direction free slip automatic correction center, so the utility model discloses spiral cover automatic correction central installation sample can not incline, and measured value and actual value are more accurate, more high-efficient, also can greatly reduced instrument test error for measured data is more accurate, and work efficiency improves greatly, uses convenient and fast more.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome above-mentioned current defect and provide a spiral cover automatic correction central installation, simple structure, with low costs, stability is good, use more extensively.

The technical scheme is as follows:

a center device for automatically correcting a rotary cover comprises a horizontal fixing plate, an X-axis fixing plate, an X-direction optical axis, an XY-axis connecting plate, a Y-axis fixing plate, a Y-direction optical axis, a sensor fixing plate, a measuring head fixing plate, a torsion sensor, an upper clamp clamping cylinder, an upper clamp and a lower clamp;

the horizontal fixing plate is horizontally fixed on the fixing device, preferably, the fixing device can be used for lifting adjustment or horizontal adjustment, and samples with different heights can be measured;

two X-axis fixing plates are respectively and fixedly arranged on two sides of the horizontal fixing plate; two X-direction optical axes are fixedly arranged between the two X-axis fixing plates; the two X-direction optical axes are parallel to each other and have the same distance with the horizontal fixing plate;

the two Y-axis fixing plates are oppositely arranged, two Y-direction optical axes are arranged between the two Y-axis fixing plates and fixedly arranged at the upper ends of the two Y-axis fixing plates, and the two Y-direction optical axes are parallel to each other; the Y-direction optical axis is arranged below the X-direction optical axis, is mutually perpendicular to the X-direction optical axis but does not intersect with the X-direction optical axis, and the distance between the two Y-direction optical axes is the same as that between the two X-direction optical axes;

the X-direction optical axis and the Y-direction optical axis are movably connected through an XY-axis connecting plate, through holes matched with the X-direction optical axis and the Y-direction optical axis are formed in the XY-axis connecting plate, and the XY-axis connecting plate can freely slide on the X-direction optical axis and the Y-direction optical axis;

the lower end of the Y-axis fixing plate is fixedly connected to the sensor fixing plate; a torsion sensor is fixedly arranged below the sensor fixing plate; the torque sensor is electrically connected with the controller and is used for measuring the screwing force and the opening force of the sample;

the upper part of the measuring head fixing plate is fixedly connected with the measuring end of the torsion sensor, and the lower part of the measuring head fixing plate is fixedly provided with an upper clamp clamping cylinder;

the upper clamp clamping cylinder is fixedly connected with the upper clamp, the upper clamping cylinder is electrically connected with the controller, and the controller controls the upper clamping cylinder to drive the upper clamp to clamp the sample;

the fixing device is further provided with a lower clamp fixing plate, a lower clamp is fixedly arranged on the lower clamp fixing plate, the lower clamp fixing plate is movably connected with the fixing device, and the lower clamp fixing plate can rotate around the center of the lower clamp in the horizontal direction.

The fixed connection mode is through the screw connection.

The lower clamp can control to clamp the sample through a lower clamping cylinder electrically connected with the controller, and can also manually clamp the sample in a screw mode.

Has the advantages that: the utility model discloses spiral cover automatic correction central device through automatic correction vertical direction (Z axle) center, realizes anchor clamps, lower anchor clamps center on the same straight line of vertical direction for measured data is more accurate, and work efficiency improves greatly, uses convenient and fast more.

The terms of direction and position in the present invention, such as "up", "down", "front", "back", "left", "right", "inside", "outside", "top", "bottom", "side", etc., refer to the direction and position of the attached drawings. Accordingly, the use of directional and positional terms is intended to illustrate and understand the present invention and is not intended to limit the scope of the invention.

Drawings

Fig. 1(a) is a front view of the structure of the present invention;

fig. 1(b) is a left side view of the structure diagram of the present invention;

fig. 2(a) is a schematic structural view of the XY adapter plate of the present invention;

fig. 2(b) is a schematic cross-sectional view of the XY adapter plate of the present invention;

fig. 2(c) is a sectional view taken along the direction of a1 of the present invention;

fig. 2(d) is a sectional view taken along the direction of a2 of the present invention;

FIG. 3(a) is a front view of a clamping sample of the present invention;

FIG. 3(b) is a left side view of the schematic view of the clamping sample of the present invention

FIG. 4 is a schematic view of the embodiment of the present invention

In the figure: 1. a horizontal fixing plate; 2. an X-axis fixing plate; 3. an X-direction optical axis; 4. an XY patch board; 5. a Y-axis fixing plate; 6. a Y-direction optical axis; 7. a sensor fixing plate; 8. a measuring head fixing plate; 9. a torque sensor; 10. an upper clamp clamps the cylinder; 11. an upper clamp; 12. a lower clamp; 13. a sample; 14. a Y-direction hole; 15. an X-direction hole; 16. a lift adjustment device; 17. a lower clamp fixing plate; 18. a fixing device; 19. a rotating shaft; 20. level adjusting device

Detailed Description

The invention will now be further described with reference to the accompanying drawings. The figures are simplified schematic diagrams illustrating the basic structure of the present invention only in a schematic manner, and therefore show only the components related to the present invention.

Referring to fig. 1-4, the utility model discloses a spiral cover automatic correction center device frock includes: a horizontal fixing plate 1; an X-axis fixing plate 2; an X-direction optical axis 3; an XY-axis adapter plate 4; a Y-axis fixing plate 5; a Y-direction optical axis 6; a sensor fixing plate 7; a measuring head fixing plate 8; a torque sensor 9; the upper clamp clamps the cylinder 10; an upper jig 11; a lower clamp 12; the horizontal fixing plate 1, the X-axis fixing plate 2 and the X-direction optical axis 3 are fixedly connected through screws, and the distance between the two X-direction optical axes 3 is kept consistent;

the horizontal fixing plate 1 is horizontally fixed on a fixing device 18, preferably, the fixing device 18 can be adjusted in a lifting way or in a horizontal way through a lifting adjusting device, and samples with different heights can be measured;

two X-axis fixing plates 2 are respectively and fixedly arranged on two sides of the horizontal fixing plate 1, and the two X-axis fixing plates 2 are parallel to each other; two X-direction optical axes 3 are fixedly arranged between the two X-axis fixing plates 2; the two X-direction optical axes 3 are parallel to each other and have the same distance with the horizontal fixing plate 1;

the two Y-axis fixing plates 5 are oppositely arranged in parallel, two Y-direction optical axes 6 are arranged between the two Y-axis fixing plates 5 and are fixedly arranged at the upper ends of the two Y-axis fixing plates 5, and the two Y-direction optical axes 6 are parallel to each other; the Y-direction optical axis 6 is arranged below the X-direction optical axis 3, is perpendicular to the X-direction optical axis 3 but does not intersect with the X-direction optical axis 3, and the distances between the two Y-direction optical axes 6 and the two X-direction optical axes 3 are the same;

the X-direction optical axis and the Y-direction optical axis are movably connected through an XY-axis connecting plate 4, through holes matched with the X-direction optical axis 3 and the Y-direction optical axis 6 are formed in the XY-axis connecting plate 4, and the XY-axis connecting plate 4 can freely slide on the X-direction optical axis 3 and the Y-direction optical axis 6;

the lower end of the Y-axis fixing plate 6 is fixedly connected to the sensor fixing plate 7; a torsion sensor 9 is fixedly arranged below the sensor fixing plate 7; the torque sensor 9 is electrically connected with the controller and is used for measuring the screwing force and the opening force of the sample;

when the X-axis optical axis X-axis adapter plate is installed, the X-axis hole of the XY-axis adapter plate 4 is inserted into the X-axis optical axis 3 and can freely slide; the Y-axis fixing plate 5 is connected with the Y-direction optical axis 6, the sensor fixing plate 7 and the torsion sensor 9 through screws, and meanwhile, a Y-direction hole of the XY-axis connecting plate 4 is inserted into the Y-direction optical axis 6 and can freely slide; the measuring head fixing plate 8 is connected with the upper clamp clamping cylinder 10 and the upper clamp 11 through screws, and the measuring head fixing plate 8 is fixed on the measuring head at the lower end of the torsion sensor 9.

The upper part of the measuring head fixing plate 8 is fixedly connected with the measuring end of the torsion sensor 9, and the lower part is fixedly provided with an upper clamp clamping cylinder 10;

the upper clamp clamping cylinder 10 is fixedly connected with an upper clamp 11, the upper clamp clamping cylinder 10 is electrically connected with a controller, and the controller controls the upper clamp clamping cylinder 10 to drive the upper clamp 11 to clamp a sample 13;

the fixing device is further provided with a lower clamp fixing plate 17, a lower clamp 12 is fixedly arranged on the lower clamp fixing plate 17, the lower clamp fixing plate 17 is movably connected with the fixing device and can rotate around the center of the lower clamp 12 in the horizontal direction, and the rotating function can be achieved by arranging a rotating shaft 19 in the center of the lower clamp fixing plate 17.

The fixing device is also provided with a lifting adjusting device 16 which can carry out lifting adjustment.

The fixing device is movably connected with the horizontal fixing plate through a horizontal adjusting device 20, so that the horizontal fixing plate 1 can horizontally slide on the fixing device.

The fixing device and the horizontal fixing plate can be movably connected through a sliding rail, so that the horizontal fixing plate can horizontally slide on the fixing device.

The fixed connection mode is through the screw connection.

The lower clamp 12 can control to clamp the sample through a lower clamping cylinder electrically connected with a controller, and can also manually clamp the sample in a screw mode.

When the test operation is performed, an operator clamps the sample 13 on the lower clamp 12, and the lower clamp 12 is electrically connected with the torque tester. Adjusting horizontal fixed plate 1, make upper fixture 11 and lower anchor clamps 12 center be basically perpendicular, the controller control goes up anchor clamps clamping cylinder 10 and then control upper fixture 11 and press from both sides tight sample 13, after upper fixture 11 presss from both sides tight sample 13, control lower anchor clamps fixed plate 12 and rotate, upper fixture 11 is under the effect of the rotational torque of lower anchor clamps 13, through freely sliding on X, Y direction optical axis of horizontal direction by itself, Z axle direction torsion is not influenced by any, automatic correction vertical direction Z axle center, realize upper fixture, lower anchor clamps center is on the same straight line of vertical direction, make measured data more accurate, work efficiency improves greatly, use convenient and fast more.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described in the foregoing embodiments, or equivalents may be substituted for elements thereof. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. A center device for automatically correcting a rotary cover comprises a fixing device and is characterized in that the center device for automatically correcting the rotary cover comprises a horizontal fixing plate, an X-axis fixing plate, an X-direction optical axis, an XY-axis transfer plate, a Y-axis fixing plate, a Y-direction optical axis, a sensor fixing plate, a measuring head fixing plate, a torsion sensor, an upper clamp clamping cylinder and an upper clamp;

the horizontal fixing plate is horizontally fixed on the fixing device, and two X-axis fixing plates are respectively and fixedly arranged on two sides of the horizontal fixing plate; two X-direction optical axes are fixedly arranged between the two X-axis fixing plates; the two X-direction optical axes are parallel to each other and have the same distance with the horizontal fixing plate;

the two Y-axis fixing plates are oppositely arranged, two Y-direction optical axes are arranged between the two Y-axis fixing plates and fixedly arranged at the upper ends of the two Y-axis fixing plates, and the two Y-direction optical axes are parallel to each other; the Y-direction optical axis is arranged below the X-direction optical axis, is mutually perpendicular to the X-direction optical axis but does not intersect with the X-direction optical axis, and the distance between the two Y-direction optical axes is the same as that between the two X-direction optical axes;

the X-direction optical axis and the Y-direction optical axis are movably connected through an XY-axis connecting plate, and through holes matched with the X-direction optical axis and the Y-direction optical axis are formed in the XY-axis connecting plate, so that the XY-axis connecting plate can freely slide on the X-direction optical axis and the Y-direction optical axis;

the lower end of the Y-axis fixing plate is fixedly connected to the sensor fixing plate; a torsion sensor is fixedly arranged below the sensor fixing plate;

the upper part of the measuring head fixing plate is fixedly connected with the measuring end of the torsion sensor, and the lower part of the measuring head fixing plate is fixedly provided with an upper clamp clamping cylinder;

and the upper clamp clamping cylinder is fixedly connected with the upper clamp.

2. The automatic center correcting device for the screw cap as claimed in claim 1, further comprising a controller, wherein the torque sensor is electrically connected to the controller, the upper clamping cylinder is electrically connected to the controller, and the controller controls the upper clamping cylinder to drive the upper clamp to clamp the sample.

3. The automatic center correcting device for the screw cap according to claim 1, wherein the fixing device is further provided with a lower clamp fixing plate, the lower clamp fixing plate is fixedly provided with a lower clamp, and the lower clamp fixing plate is movably connected with the fixing device and can rotate around the center of the lower clamp in the horizontal direction.

4. The automatic center correcting device for the screw cap according to claim 1, wherein the fixing device is further provided with a lifting adjusting device capable of performing lifting adjustment.

5. The automatic center correcting device for the screw cap as claimed in claim 4, wherein the fixing means is movably connected to the horizontal fixing plate by a horizontal adjusting means so that the horizontal fixing plate can slide horizontally on the fixing means.

6. The automatic center correcting device for the screw cap as claimed in claim 5, wherein the fixing device is movably connected with the horizontal fixing plate by a horizontal adjusting device, and the horizontal adjusting device is a slide rail.

7. The center device for automatically correcting the cover screwing of claim 1, wherein the fixed connection is realized by a screw connection.

8. The automatic center correcting device for the screw cap according to claim 3, wherein the lower clamp fixing plate is centrally provided with a rotating shaft.

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