CN110552511A - sliding structure with automatic monitoring device and movement control method - Google Patents

Abstract

the invention discloses a sliding structure with an automatic monitoring device, which comprises an embedded part; the embedded part is provided with a track which is fixedly connected with the embedded part; the track is provided with a sliding structure, and the sliding structure is connected with the track in a sliding manner; a component bottom plate is arranged above the sliding structure; the component bottom plate is fixedly connected with the sliding structure; a supporting component is fixedly arranged above the component bottom plate; the sliding structure is connected with a distance measuring sensor, and the distance measuring sensor is arranged on two sides of the track; the target is arranged on one side of the end part of the track; one of the distance measuring sensors is arranged towards the target, and a reflector plate is arranged on the target; another ranging sensor is disposed toward the track. The method for controlling the movement of the sliding structure comprises the following specific steps: 1) monitoring a value between one ranging sensor and the reflecting plate and a value between the other ranging sensor and the track as initial values; 2) and comparing the value in the moving process with the initial value, and judging whether the supporting member deviates or not according to the difference value.

Description

sliding structure with automatic monitoring device and movement control method

Technical Field

The invention belongs to the field of buildings, and particularly relates to a sliding structure with an automatic monitoring device and a movement control method.

Background

The steel structure truss and the platform are in a mature technology, the sliding support is in a form that a horizontal steel plate is welded with a vertical support rod piece of a member, and the steel plate is in direct contact with a sliding steel rail. And limiting blocks are welded on two sides of the bottom of the steel plate, and the relative position of the support in the transverse direction of the steel rail is observed manually in the sliding process, so that the pressure of the left hydraulic ejector and the pressure of the right hydraulic ejector are convenient to adjust.

The traditional platform has the following disadvantages:

1. The steel plate at the bottom of the sliding support cannot be reused;

2. When the steel plate meets the joint part of the steel rail, the jacking resistance phenomenon during sliding is easy to occur due to the unevenness of the joint part of the steel rail;

3. when the relative position of the support and the transverse direction of the steel rail is manually observed, the high-altitude operation is adopted, a conventional platform is not utilized, machinery such as a high-altitude vehicle is required, and automatic real-time monitoring cannot be realized;

4. the displacement of the component in the longitudinal direction of the steel rail during sliding is generally measured by two workers at the two steel rails respectively by using steel rulers, and the displacement is reported to an operator by using an interphone, the interphones on the same channel cannot realize simultaneous communication, so that the phenomenon of report delay is easy to occur, and the control error of the operator is caused to cause the left and right deviation of the sliding component.

Disclosure of Invention

The purpose of the invention is as follows: the invention aims to solve the defects in the prior art and provides a sliding structure with an automatic monitoring device and a movement control method.

the technical scheme is as follows: the invention relates to a sliding structure with an automatic monitoring device, which comprises an embedded part;

The embedded part is provided with a track which is fixedly connected with the embedded part;

the track is provided with a sliding structure, and the sliding structure is connected with the track in a sliding manner;

A component bottom plate is arranged above the sliding structure; the component bottom plate is fixedly connected with the sliding structure; a supporting component is fixedly arranged above the component bottom plate;

The sliding structure is connected with a distance measuring sensor, and the distance measuring sensor is arranged on two sides of the track;

the target is arranged on one side of the end part of the track; one of the distance measuring sensors is arranged towards the target, and a reflector plate is arranged on the target; another ranging sensor is disposed toward the track.

the invention has the further improvement that the sliding structure comprises round steel, a pair of mounting plates and a horizontal plate; the mounting plate is provided with a groove, and two ends of the round steel are fixed in the groove of the mounting plate; the arranging direction of the round steel is vertical to the extending direction of the track; the horizontal plate is arranged above the mounting plate; the horizontal plate is fixedly connected with the mounting plate;

The component bottom plate is arranged above the horizontal plate, a backing plate is arranged above the component bottom plate, and the backing plate and the component bottom plate are fixedly connected with the horizontal plate through bolts; after the base plate and the component bottom plate are fixed through bolts, the bottom of the base plate is connected with the component bottom plate in a welding mode;

The ranging sensor is connected with the ranging sensor connecting plate, the ranging sensor connecting plate is fixedly connected with the mounting plate, the ranging sensor connecting plate is vertically arranged downwards, the arrangement direction of the ranging sensor connecting plate is consistent with the direction of the transverse central line of the round steel, and the ranging sensor connecting plate is arranged at the end of the mounting plate.

the invention has the further improvement that the distance measuring sensor at the target side is fixed on an angle iron support which is fixedly connected with a connecting plate of the distance measuring sensor through a connecting conversion plate; the connecting and converting plate is L-shaped, and a transverse plate at the bottom of the connecting and converting plate protrudes below the connecting plate of the distance measuring sensor; the angle iron support corresponding to the target side is fixedly connected to the bottom transverse plate connected with the conversion plate; and the angle iron support connected with the other distance measuring sensor is directly and fixedly connected with the distance measuring sensor connecting plate.

The invention is further improved in that the round steel is a pair.

the embedded part is connected with the track through the track pressing block, the track pressing block is provided with a notch, the track is clamped in the notch of the track pressing block, and the track pressing block is connected with the track and the embedded part through welding.

the invention has the further improvement that the track pressing block is provided with a mounting hole, and the target is fixedly connected with the mounting hole of the track pressing block through a bolt.

The invention is further improved in that the supporting member is formed by welding criss-cross vertical plates.

a movement control method of a sliding structure with an automatic monitoring device comprises the following specific steps:

1) monitoring a value between one ranging sensor and the reflecting plate and a value between the other ranging sensor and the track as initial values;

2) And comparing the value in the moving process with the initial value, and judging whether the supporting member deviates or not according to the difference value.

The invention is further improved in that the difference value in the step 2) is displayed on a control terminal, and the movement of the supporting member is controlled according to the displayed difference value.

Compared with the prior art, the sliding structure with the automatic monitoring device and the movement control method provided by the invention at least realize the following beneficial effects:

1. The sliding structure is connected through a bolt and can be repeatedly utilized;

2. The two round steel are contacted with the track, so that the friction resistance is small, the sliding thrust is small, the steel rail joint part with the height difference can pass through more favorably, and the phenomenon that the steel rail joint is blocked to slide is not easy to occur;

3. The arrangement of the measuring and ranging sensor does not need to manually utilize mechanical equipment such as a high-altitude vehicle and the like to observe the transverse relative position of the support and the steel rail, is safer and more efficient, and saves the cost.

4. The measuring and ranging sensor is a high-precision industrial infrared ranging sensor, the sliding distance of the sliding component in the longitudinal direction of the steel rail is detected in real time through the high-precision industrial infrared ranging sensor, a worker does not need to pull a ruler for counting, the defect that the interphone on the same channel cannot realize simultaneous conversation is overcome, and the pressure of the hydraulic pushing oil pump is adjusted in real time through numerical value display and position simulation, so that an operator can observe the pressure in real time and control the pressure in real time.

Of course, it is not specifically necessary for any one product that implements the invention to achieve all of the above-described technical effects simultaneously.

Other features of the present invention and advantages thereof will become apparent from the following detailed description of exemplary embodiments thereof, which proceeds with reference to the accompanying drawings.

Drawings

the accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description, serve to explain the principles of the invention.

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the connection structure of the track, the pressing block and the embedded part;

FIG. 3 is a schematic layout of a range sensor according to the present invention;

FIG. 4 is a schematic structural view of the glide structure and the component base plate of the present invention;

FIG. 5 is a schematic structural view of the sliding structure of the present invention;

FIG. 6 is a schematic structural view of a base plate of the present invention;

FIG. 7 is a schematic view of a connection structure of a distance measuring sensor and an angle iron support;

FIG. 8 is a schematic view of the connection structure of the distance measuring sensor, the angle iron support and the connection conversion plate;

Wherein, 1-round steel; 2-mounting a plate; 3-horizontal plate; 4-a backing plate; 5-connecting a ranging sensor board; 6-bolt; 7-a ranging sensor; 8-connecting a conversion plate; 9-angle iron support; 10-end head closing plate; 12-rail briquetting; 15-track; 16-a buried member; 17-a slip structure; 18-a component base plate; 19-a support member.

Detailed Description

Various exemplary embodiments of the present invention will now be described in detail with reference to the accompanying drawings. It should be noted that: the relative arrangement of the components and steps, the numerical expressions and numerical values set forth in these embodiments do not limit the scope of the present invention unless specifically stated otherwise.

the following description of at least one exemplary embodiment is merely illustrative in nature and is in no way intended to limit the invention, its application, or uses.

Techniques, methods, and apparatus known to those of ordinary skill in the relevant art may not be discussed in detail but are intended to be part of the specification where appropriate.

in all examples shown and discussed herein, any particular value should be construed as merely illustrative, and not limiting. Thus, other examples of the exemplary embodiments may have different values.

it should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, further discussion thereof is not required in subsequent figures.

In the case of the example 1, the following examples are given,

As shown in fig. 1-8, a sliding structure with an automatic monitoring device comprises an embedded part 16;

A track 15 is arranged on the embedded part 16 and is fixedly connected with the embedded part 16;

A sliding structure 17 is arranged on the track 15, and the sliding structure 17 is connected with the track 15 in a sliding manner;

A component bottom plate 18 is arranged above the sliding structure 17; the component bottom plate 18 is fixedly connected with the sliding structure 17 through bolts; a supporting component 19 is fixedly arranged above the component bottom plate 18; each bottom plate is provided with 8 transverse long circular holes, and the transverse long circular holes are used for facilitating fine adjustment of the position of the sliding structure 17 according to the actual position of the track, so that the sliding structure 17 is aligned with the track in the middle;

The sliding structure 17 is connected with the distance measuring sensor 7, and the distance measuring sensor 7 is arranged on two sides of the track 15;

a target 14, which is arranged on one side of the end part of the track 15; one of the distance measuring sensors 7 is arranged towards the target 14, and a reflector plate is arranged on the target 14; the further distance measuring sensor 7 is arranged towards the track 15.

In this embodiment, the track 15 is a 46 gauge steel rail.

based on the above embodiment, when measuring the distance from the distance measuring sensor 7 to the track 15, the sighting direction of the distance measuring sensor 7 is set to be perpendicular to the track, and the initial distance is set to be 80mm from the track surface. Another distance measuring sensor 7 illuminates a reflector plate on the target 14 to obtain the distance of the sliding structure 17 from the end of the track 15.

when measuring and rail fore-and-aft distance, will range sensor's direction of alighting parallel with the track, will mark target 14 and pass through No. 13 bolts and be connected with No. 12 track briquetting, on mark target No. 4, paste the reflector plate with the corresponding horizontal position of range sensor, shine the reflector plate on mark target 14 through measuring range sensor 7, reachs the fore-and-aft distance of sliding support and track, the range sensor laser irradiation of being convenient for is measured.

To further explain the embodiment, it should be noted that the sliding structure 17 includes a round steel 1, a pair of mounting plates 2, and a horizontal plate 3; a groove is arranged on the mounting plate 2, and two ends of the round steel 1 are fixed in the groove of the mounting plate 2; the arranging direction of the round steel 1 is vertical to the extending direction of the track 15; the horizontal plate 3 is arranged above the mounting plate 2; the horizontal plate 3 is fixedly connected with the mounting plate 2;

the component bottom plate 18 is arranged above the horizontal plate 3, the backing plate 4 is arranged above the component bottom plate 18, and the backing plate 4 and the component bottom plate 18 are fixedly connected with the horizontal plate 3 through bolts 6; the backing plate 4 and the component bottom plate 18 are fixed through the bolts 6 and then connected through the bolts, so that the materials can be repeatedly used. In this embodiment, the round steel 1 has a diameter of 50mm and is made of 45 # steel.

Ranging sensor 7 links to each other with ranging sensor connecting plate 5, and ranging sensor connecting plate 5 links to each other with mounting panel 2 is fixed, and ranging sensor connecting plate 5 is vertical sets up downwards, and ranging sensor connecting plate 5's the direction of furnishing is unanimous with the horizontal central line direction of round steel 1, and ranging sensor connecting plate 5 locates the tip of mounting panel 2.

in this embodiment, specifically, the measuring and ranging sensor 7 may be installed in front of the sliding structure 17 or in the rear.

for further explanation of the present embodiment, it should be noted that the distance measuring sensor 7 on the target 14 side is fixed on the angle iron support 9, and the angle iron support 9 is fixedly connected with the distance measuring sensor connecting plate 5 through the connecting and converting plate 8; the connecting and converting plate 8 is L-shaped, and a bottom transverse plate of the connecting and converting plate 8 protrudes below the connecting plate 5 of the distance measuring sensor; the angle iron support 9 corresponding to the target 14 side is fixedly connected to the bottom transverse plate connected with the conversion plate 8; and an angle iron support 9 connected with the other distance measuring sensor 7 is directly and fixedly connected with the distance measuring sensor connecting plate 5. In this embodiment, the distance measuring sensor 7 on the angle iron support 9 is welded with the end sealing plate 10 on the opposite side of the angle iron support 9.

To further explain the present embodiment, it should be noted that the round steel 1 is a pair.

for further explanation of the present embodiment, it should be noted that the embedded part 16 is connected to the rail 15 through the rail pressing block 12, the rail pressing block 12 is provided with a notch, the rail 15 is clamped in the notch of the rail pressing block 12, and the rail pressing block 12 is connected to the rail 15 and the embedded part 16 by welding.

For further explanation of the present embodiment, it should be noted that the track block 12 is provided with mounting holes, and the target 14 is fixedly connected to the mounting holes of the track block 12 through bolts. The target 14 is fixed to the track block 12 to form a relatively stationary reference point and the variation in the measured value is determined by irradiating the target. The actual sliding distance of the whole component in the sliding process can be obtained through the change of the numerical value and the comparison with the initial numerical value.

To further explain the present embodiment, it should be noted that the supporting member 19 is formed by welding criss-cross risers.

in the case of the example 2, the following examples are given,

a movement control method of a sliding structure with an automatic monitoring device comprises the following specific steps:

1) monitoring a value between the distance measuring sensor 7 and the reflection plate and a value between the other distance measuring sensor 7 and the rail 15 as initial values;

2) the value during the movement is compared with the initial value, and whether the support member 19 is displaced is determined based on the difference.

It is also necessary to store an initial value N1 in the device, and after the movement has started, the difference between the real time value and the initial value indicates the actual slip distance. Due to the characteristics of the stroke of the hydraulic oil pump, in a pushing stroke (different equipment strokes are different, in this case, one stroke is 250 mm), the sliding is generally 100mm, the observation is suspended once, the left pushing sliding distance and the right pushing sliding distance are observed to be the same at the same time, and if the two sliding distances are different, the adjustment is carried out, so that the left pushing point and the right pushing point are synchronously carried out.

Therefore, the difference between the real-time values of the left and right measuring devices and the initial values needs to be compared to see which point is advanced or delayed.

to further explain the present embodiment, it should be noted that the difference value in step 2) is displayed on the control terminal, and the movement of the supporting member 19 is controlled according to the displayed difference value. The pushing and sliding construction method is a mature technology, but the pushing process is a complicated change process, and continuous adjustment in the middle of the sliding process can be caused by deformation of components, unevenness or bending of a track, uneven pressure of a hydraulic oil pump, overlong pipelines and errors or mistakes during observation of personnel. The laser measurement of the device makes the data measurement more accurate, and the reaction is more real-time, in the display processing, can be more directly perceived easily with the change of data conversion image.

in this embodiment, whether the whole member is shifted in the sliding process can be obtained by monitoring the distance between the distance measuring sensor 7 and the track, and by changing the value and comparing the value with the initial value.

By the embodiment, the sliding structure with the automatic monitoring device and the movement control method provided by the invention at least realize the following beneficial effects:

1. The sliding structure 17 is connected through bolts and can be repeatedly used;

2. the two round steel 1 are in contact with the track 15, so that the friction resistance is small, the sliding thrust is small, the steel rail joint part with the height difference can pass through more favorably, and the phenomenon of top resistance sliding of the steel rail joint is not easy to occur;

3. The arrangement of the measuring and ranging sensor 7 does not need to manually utilize mechanical equipment such as a high-altitude vehicle and the like to observe the transverse relative position of the support and the steel rail, is safer and more efficient, and saves the cost.

4. The measuring and ranging sensor 7 is a high-precision industrial infrared ranging sensor, and can detect the sliding distance of the sliding component in the longitudinal direction of the steel rail in real time through the high-precision industrial infrared ranging sensor without the need of a worker for pulling a ruler for counting, so that the defect that the interphone on the same channel cannot realize simultaneous conversation is overcome, and the pressure of the hydraulic pushing oil pump is conveniently observed by an operator in real time and controlled in real time through numerical value display and position simulation.

Although some specific embodiments of the present invention have been described in detail by way of examples, it should be understood by those skilled in the art that the above examples are for illustrative purposes only and are not intended to limit the scope of the present invention. It will be appreciated by those skilled in the art that modifications may be made to the above embodiments without departing from the scope and spirit of the invention. The scope of the invention is defined by the appended claims.

Claims (9)

1. A gliding structure with automatic monitoring, characterized in that it comprises an insert (16);

A track (15) is arranged on the embedded part (16), and the track is fixedly connected with the embedded part (16);

A sliding structure (17) is arranged on the track (15), and the sliding structure (17) is connected with the track (15) in a sliding manner;

A component bottom plate (18) is arranged above the sliding structure (17); the component bottom plate (18) is fixedly connected with the sliding structure (17); a supporting component (19) is fixedly arranged above the component bottom plate (18);

the sliding structure (17) is connected with a distance measuring sensor (7), and the distance measuring sensor (7) is arranged on two sides of the track (15);

a target (14) arranged on one side of the end part of the track (15); wherein one of the distance measuring sensors (7) is arranged towards the target (14), and a reflector plate is arranged on the target (14); the other distance measuring sensor (7) is arranged towards the track (15).

2. The sliding structure with automatic monitoring device according to claim 1,

The sliding structure (17) comprises round steel (1), a pair of mounting plates (2) and a horizontal plate (3); a groove is formed in the mounting plate (2), and two ends of the round steel (1) are fixed in the groove of the mounting plate (2);

The arrangement direction of the round steel (1) is vertical to the extending direction of the track (15);

the horizontal plate (3) is arranged above the mounting plate (2); the horizontal plate (3) is fixedly connected with the mounting plate (2);

The component bottom plate (18) is arranged above the horizontal plate (3), a backing plate (4) is arranged above the component bottom plate (18), and the backing plate (4) and the component bottom plate (18) are fixedly connected with the horizontal plate (3) through bolts (6); after the backing plate (4) and the component bottom plate (18) are fixed through bolts (6), the bottom of the backing plate (4) is connected with the component bottom plate (18) in a welding mode;

range sensor (7) link to each other with range sensor connecting plate (5), range sensor connecting plate (5) with mounting panel (2) are fixed continuous, range sensor connecting plate (5) vertical downward setting, the direction is established to the pendulum of range sensor connecting plate (5) with the horizontal central line direction of round steel (1) is unanimous, range sensor connecting plate (5) are located the tip of mounting panel (2).

3. a skid structure having an automatic monitoring device according to claim 2,

The distance measuring sensor (7) on the target (14) side is fixed on an angle iron support (9), and the angle iron support (9) is fixedly connected with the distance measuring sensor connecting plate (5) through a connecting and converting plate (8); the connection conversion plate (8) is L-shaped, and a bottom transverse plate of the connection conversion plate (8) protrudes below the ranging sensor connecting plate (5); the angle iron support (9) corresponding to the target (14) side is fixedly connected to the bottom transverse plate of the connecting and converting plate (8);

and the angle iron support (9) connected with the other distance measuring sensor (7) is directly and fixedly connected with the distance measuring sensor connecting plate (5).

4. A sliding structure with automatic monitoring device according to claim 1, characterized in that the round steel (1) is a pair.

5. The sliding structure with the automatic monitoring device is characterized in that the embedded part (16) is connected with the rail (15) through a rail pressing block (12), a notch is formed in the rail pressing block (12), the rail (15) is clamped in the notch of the rail pressing block (12), and the rail pressing block (12) is connected with the rail (15) and the embedded part (16) through welding.

6. The sliding structure with the automatic monitoring device is characterized in that the track pressing block (12) is provided with a mounting hole, and the target (14) is fixedly connected with the mounting hole of the track pressing block (12) through a bolt.

7. A sliding structure with automatic monitoring device according to claim 1, characterized in that the support element (19) is welded with criss-cross risers.

8. The movement control method of the sliding structure with the automatic monitoring device according to claim 1 is characterized by comprising the following specific steps:

(1) Monitoring, as initial values, the value between the distance sensor (7) and the reflector plate and the value between the other distance sensor (7) and the rail (15);

(2) The value during the movement is compared with the initial value, and whether the support member (19) is deviated or not is judged according to the difference value.

9. the method of claim 8, wherein the difference value in the step (2) is displayed on a control terminal, and the movement of the support member (19) is controlled according to the displayed difference value.