CN108457948B - Full-automatic sticking device for resistance strain gauge - Google Patents

Abstract

The utility model discloses a full-automatic pasting device for a resistance strain gauge. Including fixed box, sliding support, grinding device, rubberizing device, paster device, pressing device, the second motor, first motor, dust collector and power, fixed box one side is provided with the power, the power is connected with the second motor respectively, first motor electricity, first motor links to each other with sliding support, be provided with grinding device on the sliding support respectively, rubberizing device, paster device, pressing device, dust collector sets up in grinding device one side, grinding device, rubberizing device, paster device, pressing device and dust collector all link to each other with the second motor, fixed box bottom still is provided with the handle, sliding support sets up on the slip track in fixed box, still be provided with resistance strain gauge on the fixed box and paste the hole. The utility model can greatly improve the pasting quality and efficiency of the resistance strain gauge and save the operation time. The utility model can effectively eliminate the artificial influence in the process of pasting the resistance strain gauge, so that the accuracy and the reliability of the engineering structure strain test can be greatly improved.

Description

Full-automatic sticking device for resistance strain gauge

Technical Field

The utility model relates to the technical field of engineering structure testing, in particular to a full-automatic sticking device for a resistance strain gauge.

Background

In engineering structure testing, strain measurement is a common test method for stress analysis of an actual structure. As the most commonly used strain gauge type, the adhesion quality of the resistance strain gauge is one of the key factors for judging whether the experimental result is reliable. In the engineering structure test, the sticking of the resistance strain gauge is completely manually operated by an experimenter. However, the subjective factors and the proficiency of the testers have great influence on the pasting quality due to the fact that the steps and the processes of the resistor strain gauge pasting work are multiple and complex.

In the patent of the utility model (issued bulletin number: CN 206439263U; name: a novel bridge floor strain gauge sticking instrument) issued in 2017, 8 and 25, a manual strain gauge sticking mechanical device is proposed. When the novel bridge bottom plate strain gauge pasting instrument is used, firstly, a strain gauge is placed on a strain gauge base, glue is filled in a glue box, then the handle is lifted to align the strain gauge base of the novel bridge bottom plate strain gauge pasting instrument to a position where the strain gauge needs to be arranged, then upward thrust is applied to the handle, the thrust is transmitted to a bracket through a supporting rod, the bracket rolls in a sliding groove through a roller of the bracket, at the moment, a spring receives compression force, a squeezing plate and the bracket glue box are sprayed on the pasting surface of the strain gauge from a glue nozzle, the handle is further pushed, the pasting surface of the strain gauge is contacted with a box girder bottom plate, after 5-l0 seconds, the strain gauge is well pasted on the box girder bottom plate, then the thrust on the handle is removed, and the instrument is restored to a restoring state under the action of the spring. It has the following disadvantages: 1) The existing device cannot carry out the operation steps of polishing, dedusting, pressing and the like on the surface of the structure, and the steps also need manual operation. 2) Glue is directly sprayed on the resistance strain gauge, and the dosage is not easy to control. Too much glue, the resistance strain gauge is easy to adhere to the base; too little glue, the resistance strain gauge is not easy to adhere to the surface of the test structure.

At present, the pasting work of the resistance strain gauge including the procedures of polishing, dedusting, pasting, pressing and the like is mainly finished manually by testers, the pasting quality completely depends on subjective attitudes and proficiency of the testers, and the pasting quality is not guaranteed.

In summary, the present utility model provides an automatic sticking device for a resistance strain gauge.

Disclosure of Invention

Aiming at the defects existing in the prior art, the utility model aims to provide the full-automatic pasting device for the resistance strain gauge, which can greatly improve pasting quality and efficiency, save operation time, effectively eliminate artificial influence and greatly improve the accuracy and reliability of engineering structure test results.

In order to achieve the above object, the present utility model is realized by the following technical scheme: the utility model provides a full-automatic device of pasting of resistance strain gauge, including fixed box, sliding carrier, grinding device, rubberizing device, paster device, press device, the second motor, first motor, dust collector and power, fixed box one side is provided with the power, the power is connected with the second motor, first motor electricity respectively, first motor links to each other with sliding carrier, be provided with grinding device on the sliding carrier respectively, rubberizing device, paster device, press device, dust collector sets up in grinding device one side, grinding device, rubberizing device, paster device, press device and dust collector all link to each other with the second motor, fixed bottom of the case portion still is provided with the handle, sliding carrier sets up on the slip track in fixed box, still be provided with resistance strain gauge paste hole on the fixed box.

Preferably, the patch device comprises a rotating shaft spanner, a strain gauge bin and a rotating shaft, wherein one end of the rotating shaft is provided with the rotating shaft spanner, and a circle of strain gauge bin is arranged outside the rotating shaft.

Preferably, the polishing device comprises a polishing grinding wheel, a polishing transmission block and a polishing screw, wherein the polishing transmission block is arranged on the polishing screw, and the polishing grinding wheel is arranged at the end part of the polishing transmission block.

Preferably, the gluing device comprises a gluing screw, a gluing transmission block and a gluing box, wherein the gluing transmission block is arranged on the gluing screw, and the end part of the gluing transmission block is provided with the gluing box.

Preferably, the pressing device comprises a pressing screw rod, a pressing transmission block and a pressing wheel, wherein the pressing transmission block is arranged on the pressing screw rod, and the pressing wheel is arranged at the end part of the pressing transmission block.

The full-automatic pasting device for the resistance strain gauge comprises the following pasting steps:

step 1: the strain gauge bin is rotated by the rotating shaft wrench, so that a certain resistance strain gauge is parallel to the top surface of the fixed box body;

step 2: the handle below the fixed box body is utilized to enable the resistance strain gauge pasting holes on the fixed box body to correspond to corresponding positions on the surface of the engineering structure, where the resistance strain gauges need to be pasted;

step 3: starting a first motor, dragging a sliding carrier along a sliding track, enabling the polishing device to correspond to the position of the sticking hole of the resistance strain gauge, and stopping the first motor;

step 4: starting a second motor, rotating a polishing screw rod, driving a polishing transmission block to move back and forth along the first toothed plate under the drive of the polishing screw rod, and polishing a strain gauge pasting position by a polishing grinding wheel; the dust removing device is synchronously started to clean the position; after the polishing process is finished, the second motor stops working;

step 5: starting a first motor, dragging a sliding carrier along a sliding track, enabling the gluing device to correspond to the position of the sticking hole of the resistance strain gauge, and stopping the first motor;

step 6: starting a second motor, rotating a gluing screw rod, driving a gluing transmission block to move back and forth along a second toothed plate under the drive of the gluing screw rod, and starting gluing operation on the pasting position of the resistance strain gauge by a glue box; after the sizing process is finished, the second motor stops working;

step 7: starting a first motor, dragging a sliding carrier along a sliding track, enabling the patch device to correspond to the position of the sticking hole of the resistance strain gauge, and stopping the first motor;

step 8: starting a second motor, rotating a pressing screw rod, driving a pressing transmission block to move back and forth along a third toothed plate under the driving of the pressing screw rod, and pressing a resistance strain gauge by a pressing wheel; after the pressing process is finished, the second motor stops working;

step 9: finishing the pasting work of the resistance strain gauge, and removing the fixed box body; the first motor is reversely started, and the sliding carrier is reset; the next resistance strain gauge is prepared for pasting.

The utility model has the beneficial effects that:

the utility model can automatically realize the steps of polishing, dedusting, sizing, pasting, pressing and the like on the surface of the structure in the process of pasting the resistance strain gauge, greatly improve the pasting quality of the resistance strain gauge, save the pasting time, thoroughly eliminate the artificial influence in the process of pasting and improve the accuracy and the reliability of test results.

Drawings

The utility model is described in detail below with reference to the drawings and the detailed description;

FIG. 1 is a component diagram of the present utility model;

fig. 2 is a schematic structural view of a patch device according to the present utility model;

FIG. 3 is a schematic diagram of step 2 of the present utility model;

FIG. 4 is a schematic diagram of step 4 of the present utility model;

FIG. 5 is a schematic view of the polishing apparatus of the present utility model;

FIG. 6 is a schematic diagram of step 5 of the present utility model;

FIG. 7 is a schematic diagram of step 6 of the present utility model;

FIG. 8 is a schematic structural view of the gluing device of the present utility model;

FIG. 9 is a schematic diagram of step 7 of the present utility model;

FIG. 10 is a schematic diagram of step 8 of the present utility model;

fig. 11 is a schematic structural view of a pressing device of the present utility model;

fig. 12 is a top view of fig. 3.

Detailed Description

The utility model is further described in connection with the following detailed description, in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the utility model easy to understand.

Referring to fig. 1 to 11, the present embodiment adopts the following technical scheme: the utility model provides a full-automatic device of pasting of resistance strain gauge, including fixed box 1, sliding support 2, grinding device 3, rubberizing device 4, paster device 5, press device 6, second motor 7, first motor 8, dust collector 9 and power 10, fixed box 1 one side is provided with power 10, power 10 is connected with second motor 7 respectively, first motor 8 electricity, first motor 8 links to each other with sliding support 2, be provided with grinding device 3 on the sliding support 2 respectively, rubberizing device 4, paster device 5, press device 6, dust collector 9 sets up in grinding device 3 one side, grinding device 3, rubberizing device 4, paster device 5, press device 6 and dust collector 9 all link to each other with second motor 7, fixed box 1 bottom still is provided with handle 11, sliding support 2 sets up on the slip track 12 in fixed box 1, still be provided with resistance strain gauge on the fixed box 1 and paste hole 13.

It is noted that the patch device 5 comprises a rotating shaft wrench 5-1, a strain gauge bin 5-2 and a rotating shaft 5-3, wherein one end of the rotating shaft 5-3 is provided with the rotating shaft wrench 5-1, and a circle of strain gauge bin 5-2 is arranged outside the rotating shaft 5-3.

Notably, the polishing device 3 comprises a polishing grinding wheel 3-1, a polishing transmission block 3-2 and a polishing screw rod 3-3, wherein the polishing transmission block 3-2 is arranged on the polishing screw rod 3-3, and the polishing grinding wheel 3-1 is arranged at the end part of the polishing transmission block 3-2.

It is noted that the gluing device 4 comprises a gluing screw 4-1, a gluing transmission block 4-2 and a gluing box 4-3, wherein the gluing transmission block 4-2 is arranged on the gluing screw 4-1, and the gluing box 4-3 is arranged at the end part of the gluing transmission block 4-2.

It is noted that the pressing device 6 includes a pressing screw rod 6-1, a pressing transmission block 6-2 and a pressing wheel 6-3, the pressing transmission block 6-2 is disposed on the pressing screw rod 6-1, and the pressing wheel 6-3 is disposed at an end of the pressing transmission block 6-2.

In addition, the pasting steps of the full-automatic pasting device for the resistance strain gauge are as follows:

step 1: the strain gauge bin is rotated by the rotating shaft wrench, so that a certain resistance strain gauge is parallel to the top surface of the fixed box body; as shown in fig. 1 and 2.

Step 2: the handle below the fixed box body is utilized, and the resistance strain gauge pasting holes on the fixed box body are correspondingly arranged at the corresponding positions on the surface of the structure, where the resistance strain gauges need to be pasted; as shown in fig. 3.

Step 3: starting a first motor 8, pulling the sliding carrier 2 along the sliding track, and enabling the polishing device 3 to correspond to the position of the resistor strain gauge sticking hole, wherein the first motor 8 stops working;

step 4: starting a second motor 7, rotating a polishing screw rod, driving a polishing transmission block to reciprocate along a first toothed plate 14 under the drive of the polishing screw rod, and polishing a strain gauge pasting position by a polishing grinding wheel; the dust removing device 9 is synchronously started to clean the position; after the polishing process is finished, the second motor 7 stops working; as shown in fig. 4 and 5.

Step 5: starting a first motor 8, pulling the sliding carrier 2 along the sliding track, enabling the gluing device 4 to correspond to the position of the sticking hole of the resistance strain gauge, and stopping the first motor 8; as shown in fig. 6.

Step 6: starting a second motor 7, rotating a gluing screw, driving a gluing transmission block to move back and forth along a second toothed plate 15 under the drive of the gluing screw, and starting gluing operation on the pasting position of the resistance strain gauge by a glue box; after the sizing process is finished, the second motor 7 stops working; as shown in fig. 7 and 8.

Step 7: starting a first motor 8, pulling the sliding carrier 2 along the sliding track, enabling the patch device 5 to correspond to the position of the resistor strain gauge sticking hole, and stopping the first motor 8; as shown in fig. 9.

Step 8: starting the second motor 7, rotating the pressing screw rod, driving the pressing transmission block to reciprocate along the third toothed plate 16 under the driving of the pressing screw rod, and pressing the resistance strain gauge by the pressing wheel; after the pressing process is finished, the second motor 7 stops working; as shown in fig. 10 and 11.

Step 9: finishing the pasting work of the resistance strain gauge, and removing the fixed box body; the first motor 8 is reversely started, and the sliding carrier 2 is reset; the next resistance strain gauge is prepared for pasting.

In this embodiment, the track of the sliding carrier 2 may be configured in the shape of an annular track, and the components such as polishing, sizing, pressing and the like may move along the track, and may sequentially reach the resistive strain gauge attaching hole to perform corresponding operations, respectively.

The specific embodiment realizes the automation and the electrodynamic performance of all the steps of surface polishing, dust removal, sizing, pasting, pressing and the like in the process of pasting the resistance strain gauge by using the motor. And at the pasting position of the resistance strain gauge, the devices such as polishing, gluing, pasting, pressing and the like are sequentially moved, so that the pasting process of the resistance strain gauge is realized. A plurality of strain gauges can be installed in one step through the strain gauge bin, and the field operation time is shortened.

The foregoing has shown and described the basic principles and main features of the present utility model and the advantages of the present utility model. It will be understood by those skilled in the art that the present utility model is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present utility model, and various changes and modifications may be made without departing from the spirit and scope of the utility model, which is defined in the appended claims. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (2)

1. The full-automatic resistor foil gage pasting device is characterized by comprising a fixed box body (1), a sliding carrier (2), a polishing device (3), a gluing device (4), a paster device (5), a pressing device (6), a second motor (7), a first motor (8), a dust removing device (9) and a power supply (10), wherein the power supply (10) is arranged on one side of the fixed box body (1), the power supply (10) is respectively electrically connected with the second motor (7) and the first motor (8), the first motor (8) is connected with the sliding carrier (2), the polishing device (3), the gluing device (4), the paster device (5) and the pressing device (6) are respectively arranged on the sliding carrier (2), the polishing device (3), the gluing device (4), the paster device (5), the pressing device (6) and the dust removing device (9) are all connected with the second motor (7), a handle (11) is further arranged at the bottom of the fixed box body (1), the sliding carrier (2) is arranged on a sliding track (12) in the fixed box body (1), a resistor foil gage (13) is further arranged on the fixed box body (1), the first motor (8) drives the sliding carrier (2) to move along the sliding track;

the surface mounting device 5) comprises a rotating shaft spanner (5-1), a strain gauge bin (5-2) and a rotating shaft (5-3), wherein one end of the rotating shaft (5-3) is provided with the rotating shaft spanner (5-1), and the strain gauge bin (5-2) for storing resistance strain gauges is arranged outside the rotating shaft (5-3);

the polishing device (3) comprises a polishing grinding wheel (3-1), a polishing transmission block (3-2) and a polishing screw rod (3-3), wherein the polishing transmission block (3-2) is arranged on the polishing screw rod (3-3), and the polishing grinding wheel (3-1) is arranged at the end part of the polishing transmission block (3-2);

the gluing device (4) comprises a gluing screw (4-1), a gluing transmission block (4-2) and a gluing box (4-3), wherein the gluing transmission block (4-2) is arranged on the gluing screw (4-1), and the gluing box (4-3) is arranged at the end part of the gluing transmission block (4-2);

the pressing device (6) comprises a pressing screw (6-1), a pressing transmission block (6-2) and a pressing wheel (6-3), wherein the pressing transmission block (6-2) is arranged on the pressing screw (6-1), and the pressing wheel (6-3) is arranged at the end part of the pressing transmission block (6-2);

the novel tooth plate is also provided with a first tooth plate (14), a second tooth plate (15) and a third tooth plate (16); starting a second motor (7), rotating a polishing screw rod, and driving a polishing transmission block to reciprocate along a first toothed plate (14) under the drive of the polishing screw rod; starting a second motor (7), rotating the polishing screw rod, and driving the polishing transmission block to reciprocate along the first toothed plate (14) under the drive of the polishing screw rod; the second motor (7) is started, the pressing screw rod rotates, and the pressing transmission block moves back and forth along the third toothed plate (16) under the drive of the pressing screw rod.

2. A bonding method using the fully automatic bonding device for resistance strain gauge according to claim 1, comprising the steps of:

step (1): the strain gauge bin is rotated by the rotating shaft wrench, so that a certain resistance strain gauge is parallel to the top surface of the fixed box body;

step (2): the handle below the fixed box body is utilized, and the resistance strain gauge pasting holes on the fixed box body are correspondingly arranged at the corresponding positions on the surface of the structure, where the resistance strain gauges need to be pasted;

step (3): starting a first motor (8), and dragging the sliding carrier (2) along the sliding track to enable the polishing device (3) to correspond to the position of the sticking hole of the resistance strain gauge, wherein the first motor (8) stops working;

step (4): starting a second motor (7), rotating a polishing screw rod, driving a polishing transmission block to reciprocate along a first toothed plate (14) under the drive of the polishing screw rod, and polishing a strain gauge pasting position by a polishing grinding wheel; the dust removing device (9) is synchronously started to clean the position; after the polishing process is finished, the second motor (7) stops working;

step (5): starting a first motor (8), pulling the sliding carrier (2) along the sliding track, and enabling the gluing device (4) to correspond to the position of the sticking hole of the resistance strain gauge, wherein the first motor (8) stops working;

step (6): starting a second motor (7), rotating a gluing screw, driving a gluing transmission block to reciprocate along a second toothed plate (15) under the drive of the gluing screw, and starting gluing operation on the pasting position of the resistance strain gauge by a glue box; after the sizing process is finished, the second motor (7) stops working;

step (7): starting a first motor (8), pulling the sliding carrier (2) along the sliding track, and enabling the patch device (5) to correspond to the position of the sticking hole of the resistance strain gauge, wherein the first motor (8) stops working;

step (8): starting a second motor (7), rotating a pressing screw rod, driving a pressing transmission block to reciprocate along a third toothed plate (16) under the drive of the pressing screw rod, and pressing a resistance strain gauge by a pressing wheel; after the pressing process is finished, the second motor (7) stops working;

step (9): finishing the pasting work of the resistance strain gauge, and removing the fixed box body; the first motor (8) is reversely started, and the sliding carrier (2) is reset; the next resistance strain gauge is prepared for pasting.