CN210464907U - Movable integrated detection device - Google Patents

Abstract

The utility model discloses a portable integration detection device, including moving platform, the ballast box, the reaction frame, support piece, the hoist engine, the top sheave, the bottom sheave, wire rope, the ballast box sets up on moving platform, the reaction frame sets up perpendicularly on the ballast box, support piece's one end links to each other with the reaction frame, the other end links to each other with the ballast box, the top sheave sets up on the reaction frame, be located door frame's lower part, the bottom sheave sets up on the ballast box, be located the top sheave under, the hoist engine sets up on the ballast box, wire rope's on the hoist engine one end is through the top sheave, set up on the communication pole behind the bottom sheave. The utility model discloses a portable integrated detection device because with the check out test set setting on moving platform, for traditional test mode, have need not to excavate the basis, need not to beat the counter-force stake, static test, dynamic test integration operation, test speed is fast, does not receive the advantage of place restriction.

Description

Movable integrated detection device

Technical Field

The utility model belongs to the capital construction field, concretely relates to portable integrated detection device.

Background

With the development of 5G, the number of communication antennas required to be installed far exceeds the number of communication antennas installed for 4G. There is a great demand for installing communication antennas in an original communication pole station or other social pole stations (such as a municipal pole station, an electric pole station, etc.). After the communication antenna is installed in the original pole station, whether the safety performance of the structure per se is guaranteed or not needs to be comprehensively tested by static test and dynamic test on the original communication pole station, and the 5G communication antenna can be installed through the qualified original communication pole station.

When current carry out static test to communication pole station, have following not enough: it requires the field to drive the counter-force pile and has the limitation of the field size.

SUMMERY OF THE UTILITY MODEL

In order to solve the problem, the utility model provides a portable integrated detection device.

The utility model provides a portable integration detection device, such characteristic has, including moving platform, the ballast box, the reaction frame, support piece, the hoist engine, the top sheave, the bottom sheave, wire rope, wherein, the ballast box sets up on moving platform, the reaction frame is door-shaped, set up on the ballast box perpendicularly, support piece's one end links to each other with the reaction frame, the other end links to each other with the ballast box, the top sheave sets up on the reaction frame, be located the lower part of door frame, the bottom sheave sets up on the ballast box, be located the top sheave under, the hoist engine sets up on the ballast box, be located one side of reaction frame, wire rope's on the hoist engine one end is through the top sheave, set up on the communication pole behind the bottom sheave.

The utility model provides an among the portable integrated detection device, can also have such characteristic: wherein, the mobile platform is a wheeled vehicle or a tracked vehicle.

Additionally, be in the utility model provides a among the portable integrated detection device, its characterized in that still includes the tensiometer, and the tensiometer sets up the wire rope's between upper pulley and the lower pulley both ends.

Additionally, the utility model provides an among the portable integrated detection device, its characterized in that still includes sensor, data collection station, data processor, and the sensor setting is continuous with data collection station through the data line on the upper portion of communication pole, data collection station and data processor communication connection.

In addition, the utility model provides a portable integration detection device, can also have such characteristic: one end of the steel wire rope is arranged on the upper portion of the communication rod and located on the lower portion of the sensor.

Action and effect of the utility model

According to the utility model relates to a portable integrated detection device because set up check out test set on moving platform, for traditional test mode, the utility model discloses a portable integrated detection device has need not to excavate the basis, need not to beat the counter-force stake, and static test, power test integration operation, test speed is fast, does not receive the advantage of place restriction.

Drawings

Fig. 1 is a schematic diagram of a mobile integrated detection connection according to an embodiment of the present invention;

fig. 2 is a schematic top view of the mobile integrated detecting device in the embodiment of the present invention;

FIG. 3 is a view from the direction A of FIG. 2;

fig. 4 is a schematic winding diagram of the hoist according to the embodiment of the present invention.

Detailed Description

In order to make the utility model realize that technical means, creation characteristics, achievement purpose and efficiency are easily understood and known, following embodiment combines the figure to be right the utility model discloses a portable integrated detection device does specifically expounds.

Examples

As shown in fig. 1, 2, 3, and 4, the mobile integrated detection device is used for testing a communication antenna (tower) G, and the testing includes static detection and dynamic detection.

The mobile integrated detection device 100 includes a mobile unit, a static force detection unit, and a dynamic force detection unit.

The mobile unit comprises a mobile platform 11, a ballast tank 12, a reaction frame 13, two supports 14, a blocking member 15.

The mobile platform 11 is a wheeled vehicle or a tracked vehicle. In an embodiment, the mobile platform 11 is a wheeled truck, and the blocking member 15 is used to fix the wheels of the truck so that the truck cannot move.

The ballast tank 12 is disposed on the moving platform 11, and in the embodiment, the ballast tank 12 is a rectangular parallelepiped box.

The reaction frame 13 is door-shaped and is vertically arranged on the weight box 12, and two end parts of the door shape are fixedly arranged on the weight box 12.

Two support piece 14 parallel arrangement, connect the vertical pole of reaction frame 13 and ballast box 12 upper portion respectively, support piece 14's one end links to each other with reaction frame 13, and the other end links to each other with ballast box 12, and two support piece 14 all are located one side of reaction frame 13, and in the embodiment, support piece 14 is located the car rear portion.

In the embodiment, the reaction frame 13 is welded with the ballast box 12, and the ballast box 12 is welded with the longitudinal beam of the truck.

The static force detection unit comprises a winch 21, an upper pulley 22, a lower pulley 23, a steel wire rope 24, a tension meter 25, a horizontal displacement meter 26 and a theodolite.

The hoist 21 is provided on the ballast tank 12 on one side of the reaction frame and on the other side of the support member 14.

The upper pulley 22 is arranged on the reaction frame 13, in the embodiment, the upper pulley 22 is hung on the horizontal rod of the reaction frame 13 and is positioned at the lower part of the door frame.

The lower sheave 23 is provided on the ballast tank 12 directly below the upper sheave 22.

One end of a wire rope 24 on the winch 21 passes through the upper pulley 22 and is downward, passes through the lower pulley 23 and is connected with the communication rod G, and in the embodiment, a tension meter 25 is arranged at two ends of the wire rope between the upper pulley 22 and the lower pulley 23.

The power detection unit comprises a sensor 31, a data acquisition unit 32 and a data processor 33.

The sensor 31 is disposed on the upper portion of the communication rod G, and the data collector 32 and the data processor 33 are disposed on the mobile platform 11.

The sensor 31 is connected 32 to a data collector via a data line 34, and the data collector 32 is connected in communication with a data processor 33.

The data collector 32 collects data on the sensor 31,

the data processor 33 processes the data collected by the data collector 32 and outputs the processed data.

The static test process comprises the following steps:

1. one end of the wire rope 24 is fixed to the top of the rod G.

2. Placing a theodolite in the direction of 90 degrees of the horizontal projection of the steel wire rope 24; the bottom of the rod G is fitted with a horizontal displacement gauge 26.

3. The wire rope 24 is connected with the winch 21 (or the hand block) and the tension meter 25. A steel wire rope 24 on the winch 21 rounds the upper pulley 22 and is connected with one end of a tension meter 25, the other end of the tension meter 25 is connected with one end of the steel wire rope 24, and the other end of the steel wire rope 24 rounds the lower pulley 23 and is connected with the upper part of the rod G.

4. The loading was staged to 125% of the loading tension control value and the top displacement of the rod G and the top displacement of the foundation were recorded.

In the embodiment, one end of the steel wire rope 24 is arranged at the upper part of the communication rod G and is located at the lower part of the sensor 31, and F is the force direction when the steel wire rope 24 is tensioned.

Effects and effects of the embodiments

According to the portable integrated detection device that this embodiment relates, because set up check out test set on moving platform, for traditional test mode, the utility model discloses a portable integrated detection device has need not to excavate the basis, need not to beat the counter-force stake, and static test, dynamic test integration operation, testing speed is fast, does not receive the advantage of place restriction.

The above embodiments are preferred examples of the present invention, and are not intended to limit the scope of the present invention.

Claims (5)

1. A mobile integrated testing device for static and dynamic testing of a communication pole, comprising:

a movable platform, a weight box, a reaction frame, a supporting piece, a winch, an upper pulley, a lower pulley and a steel wire rope,

wherein the weight box is arranged on the mobile platform,

the reaction frame is in a door shape and is vertically arranged on the weight box,

one end of the supporting piece is connected with the reaction frame, the other end of the supporting piece is connected with the weight box,

the upper pulley is arranged on the counterforce frame and positioned at the lower part of the door frame,

the lower pulley is arranged on the weight box and is positioned right below the upper pulley,

the winch is arranged on the weight box and positioned at one side of the reaction frame,

one end of the steel wire rope on the winch passes through the upper pulley and the lower pulley and then is arranged on the communication rod.

2. The mobile integrated test device of claim 1, wherein:

wherein, the moving platform is a wheeled vehicle or a tracked vehicle.

3. The mobile integrated testing device of claim 1, further comprising:

and the tension meter is arranged at two ends of the steel wire rope between the upper pulley and the lower pulley.

4. The mobile integrated testing device of claim 1, further comprising:

a sensor, a data acquisition unit and a data processor,

the sensor is arranged at the upper part of the communication rod and is connected with the data collector through a data line,

and the data acquisition unit is in communication connection with the data processor.

5. The mobile integrated test device of claim 4, wherein:

one end of the steel wire rope is arranged on the upper portion of the communication rod and is located on the lower portion of the sensor.

Images