CN214466582U - Machine room pipe section hoisting and supporting device - Google Patents

Abstract

The utility model relates to a computer lab pipe section hoist and mount strutting arrangement belongs to the technical field of pipeline section hoist and mount support equipment. The machine room pipe section hoisting support device comprises a control device, a hoisting beam device, a crane, two guide support devices and two support seats, wherein the two guide support devices are arranged on the ground in parallel, the hoisting beam device is arranged between the two guide support devices, and the two support seats are arranged on the ground below the hoisting beam device; the machine room pipe section hoisting support system comprises a sensor module, a wireless transceiving module, a controller module and a synchronous lifting device. The utility model provides a current pipeline section hoist and mount strutting arrangement have hoisting point to hang fast inconsistent, hoist and mount precision low scheduling problem.

Description

Machine room pipe section hoisting and supporting device

Technical Field

The utility model relates to a computer lab pipe section hoist and mount strutting arrangement belongs to the technical field of pipeline section hoist and mount support equipment.

Background

In the construction process of the refrigeration machine room, in order to improve the benefit and shorten the construction period, the technology of assembling pipe sections in situ after being prefabricated in a factory and hoisting the pipe sections in place at one time is adopted; in the lifting process, the lifting speed of each lifting point is often inconsistent, the pipeline is displaced due to the fact that the pipeline and the support frame are not firmly fixed, the position of the pipeline is often readjusted after the pipeline is lifted to a preset height, the lifting precision is not guaranteed, and time and labor are consumed in adjustment; under this background, this achievement provides a computer lab pipe section hoist and mount strutting arrangement, can effective control installation accuracy, improves the installation effectiveness.

The pipeline section hoist and mount strutting arrangement of prior art has hoisting point to hang fast inconsistent, hoist and mount precision low scheduling problem, consequently, the utility model provides a machine room pipeline section hoist and mount strutting arrangement is used for solving above-mentioned problem.

SUMMERY OF THE UTILITY MODEL

Exist hoisting point in order to overcome current pipeline section hoist and mount strutting arrangement and hang fast inconsistent, hoist and mount precision low grade shortcoming, the utility model discloses a computer lab pipeline section hoist and mount strutting arrangement, the utility model discloses can the effective control installation precision, improve the installation effectiveness.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a machine room pipe section hoisting support device comprises a control device, a hanging beam device, a crane, two guide support devices and two support seats, wherein the two guide support devices are vertically arranged on the ground; the hanging beam device comprises a cross beam, at least two water pipe seats are fixedly installed at the top of the cross beam, guide plates are fixedly installed at two ends of the cross beam respectively, two rectangular grooves are longitudinally formed in the plate body, close to two sides, of each guide plate, the guide supporting device comprises a supporting column, the supporting column is hollow, two longitudinal racks are embedded in one side, close to the hanging beam device, of each supporting column, the positions of the two racks correspond to the two rectangular grooves, the bottoms of the racks are hinged to the supporting columns, a plurality of springs are arranged between the racks and the inner walls of the supporting columns, two ends of each spring are fixedly connected with the racks and the corresponding supporting columns respectively, each rack comprises a tooth part and a flat part, the tooth parts are longitudinally arranged at intervals, the flat parts are arranged between the two adjacent tooth parts, and the top end faces of the tooth parts are horizontal; the supporting seat comprises a bottom plate, a column body and a wireless transceiver, the column body is fixedly installed at the top of the bottom plate, a bellmouth is formed in the top of the column body and matched with the cross beam, a sensor device is arranged at the bottom of the bellmouth and is in communication connection with a control device through the wireless transceiver, and the control device is in communication connection with the crane through a cable.

One side of the support column, which is far away from the hanging beam device, is provided with two rows of longitudinally arranged locking screws, the positions of the two rows of locking screws correspond to the two longitudinally arranged racks, one end of each locking screw is transversely inserted into the support column and props against the racks, and the locking screws are in threaded connection with the support column.

Lifting lugs are fixedly mounted at the positions, close to the two ends, of the top of the cross beam respectively.

The number of the springs is at least three, and the springs are longitudinally arranged at intervals.

The sensor device comprises a pressure sensor and a distance sensor, wherein the pressure sensor and the distance sensor are both arranged at the bottom of the socket on the column body, and the sensor device comprises a pressure sensor which is in communication connection with the control device through a wireless transceiver.

The number of locking screws in each row is at least three.

A machine room pipe section hoisting and supporting system comprises a sensor module, a wireless transceiver module, a controller module and a synchronous hoisting device,

the sensor module comprises a pressure sensor and a distance sensor, detects pressure distribution data on the cross beam 31 and distance data between the cross beam 31 and each column body 22 in real time and sends the data to the wireless transceiving module;

the wireless transceiver module comprises a wireless transceiver, receives the pressure distribution data and the distance data and sends the pressure distribution data and the distance data to the controller module in a wireless communication mode;

the controller module comprises a control device, the controller module receives the pressure distribution data, calculates the difference A of the pressure distribution data among the columns, compares each difference A with a first threshold value one by one, and sends a shutdown instruction to the synchronous lifting device through a cable if the difference A is larger than the first threshold value, wherein the first threshold value is a value preset according to known data; the controller module receives distance data sent by the distance sensors, calculates a difference value B from the distance data sent by each distance sensor, compares each difference value B with a second threshold value one by one, and sends a shutdown instruction to the synchronous lifting device through the cable if the difference value B is larger than the second threshold value, wherein the second threshold value is a value preset according to known data;

and the synchronous lifting device receives the stop command and converts the stop command into an electric signal to control the lifting appliance to stop.

Compared with the prior art the utility model discloses there are following characteristics and beneficial effect: the utility model discloses a set up pressure sensor and distance sensor in the bellmouth of bearing, and pressure sensor and distance sensor link with controlling means, make controlling means can detect whether the crossbeam is balanced and whether the crossbeam hangs the speed the same in real time, make hoist and mount and can not produce and slide, reduced the hoist and mount deviation, increased the hoist and mount precision, prevented unexpected emergence simultaneously;

the utility model can guide the hanging beam device through the arrangement of the guide supporting device, further increases the hoisting precision, can provide support for the crossbeam after hoisting in place through the arrangement of the rack, simultaneously prevents the hanging beam device from dropping, and increases the functionality and the hoisting stability of the utility model;

the utility model can lock the rack by the locking screw after the beam is hoisted in place by the locking screw, thereby preventing accidents caused by the loosening of the spring;

the utility model discloses a sensor module, wireless transceiver module, controller module and synchronous hoisting device's setting has realized the high accuracy hoist and mount of crossbeam, and data can real time monitoring when making the crossbeam hoist and mount simultaneously to but quick response when the deviation takes place in hoist and mount.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is an enlarged view of a portion of FIG. 1;

FIG. 3 is a schematic structural view of the supporting base of the present invention;

fig. 4 is a partial cross-sectional view of a support post in the present invention;

fig. 5 is a system flow diagram of the present invention.

Wherein the reference numerals are: 10. a control device; 20. a supporting seat; 21. a base plate; 22. a column body; 221. a socket; 23. a sensor device; 231. a pressure sensor; 232. a distance sensor; 24. a wireless transceiver; 30. a beam-hanging device; 31. a cross beam; 32. a water pipe seat; 33. lifting lugs; 34. a guide plate; 341. a rectangular groove; 40. a guide support device; 41. a support pillar; 42. a rack; 421. a tooth portion; 422. a flat portion; 43. a locking screw; 44. a spring; 50. hoisting a machine; 51. a cable.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

Example 1:

as shown in fig. 1-4, the machine room pipe section hoisting support device of this embodiment includes a control device 10, a hanging beam device 30, a crane 50, two guiding support devices 40 and two support bases 20, where the two guiding support devices 40 are vertically disposed on the ground, the hanging beam device 30 is disposed between the two guiding support devices 40, and the two support bases 20 are disposed on the ground below the hanging beam device 30; the hanging beam device 30 comprises a cross beam 31, at least two water pipe seats 32 are fixedly installed at the top of the cross beam 31, guide plates 34 are fixedly installed at two ends of the cross beam 31 respectively, two rectangular grooves 341 are longitudinally formed in the plate body of each guide plate 34 close to two sides, each guide support device 40 comprises a support column 41, each support column 41 is hollow, two longitudinal racks 42 are embedded in one side of each support column 41 close to the hanging beam device 30, the positions of the two racks 42 correspond to the positions of the two rectangular grooves 341, the bottom of each rack 42 is hinged to the corresponding support column 41, a plurality of springs 44 are arranged between the racks 42 and the inner wall of each support column 41, two ends of each spring 44 are fixedly connected with the corresponding rack 42 and the corresponding support column 41 respectively, each rack 42 comprises a tooth part 421 and a flat part 422, the tooth parts 421 are longitudinally arranged at intervals, the flat parts 422 are arranged between the two adjacent tooth parts 421, and the top end surfaces of the tooth parts 421 are horizontal; the supporting seat 20 comprises a bottom plate 21, a column body 22 and a wireless transceiver 24, the column body 22 is fixedly installed at the top of the bottom plate 21, a socket 221 is formed in the top of the column body 22, the socket 221 is matched with the cross beam 31, a sensor device 23 is arranged at the bottom of the socket 221, the sensor device 23 is in communication connection with the control device 10 through the wireless transceiver 24, and the control device 10 is in communication connection with the crane 50 through a cable 51.

Furthermore, two rows of locking screws 43 are arranged in the longitudinal direction on the side of the supporting column 41 away from the hanging beam device 30, the positions of the two rows of locking screws 43 correspond to the two racks 42 arranged in the longitudinal direction, one end of each locking screw 43 is transversely inserted into the supporting column 41 and abuts against the rack 42, and the locking screws 43 are in threaded connection with the supporting column 41.

Further, lifting lugs 33 are fixedly mounted at the top of the cross beam 31 near the two ends respectively.

Further, there are at least three springs 44, and the springs 44 are longitudinally spaced.

Further, the sensor device 23 includes a pressure sensor 231 and a distance sensor 232, the pressure sensor 231 and the distance sensor 232 are both disposed at the bottom of the socket 221 on the shaft 22, and the sensor device 23 includes the pressure sensor 231 which are both in communication connection with the control device 10 through the wireless transceiver 24.

Further, the number of the locking screws 43 in each row is at least three.

Example 2:

as shown in fig. 5, the machine room pipe section hoisting support system of the embodiment includes a sensor module, a wireless transceiver module, a controller module and a synchronous lifting device,

the sensor module comprises a pressure sensor 231 and a distance sensor 232, detects pressure distribution data on the cross beam 31 and distance data between the cross beam 31 and each column body 22 in real time, and sends the data to the wireless transceiver module;

a wireless transceiver module including a wireless transceiver 24, receiving the pressure distribution data and the distance data, and transmitting the pressure distribution data and the distance data to the controller module in a wireless communication form;

a controller module, which includes a control device 10, receives the pressure distribution data, calculates a difference a of the pressure distribution data between the columns 22, and compares each difference a with a first threshold one by one, if the difference a is greater than the first threshold, a shutdown instruction is sent to the synchronous lifting device through a cable 51, and the first threshold is a value preset according to known data; the controller module receives distance data sent by the distance sensors 232, calculates a difference value B from the distance data sent by each distance sensor 232, compares each difference value B with a second threshold value one by one, and sends a shutdown instruction to the synchronous lifting device through the cable 51 if the difference value B is greater than the second threshold value, wherein the second threshold value is a value preset according to known data;

and the synchronous lifting device receives the stop command and converts the stop command into an electric signal to control the lifting appliance to stop.

The utility model discloses the principle: erecting guide supporting devices 40 at a required installation position, arranging two or more guide supporting devices 40 in parallel, erecting a cross beam 31, adjusting the position of a guide plate 34 to clamp a rack 42 in the rectangular groove 341, placing and fixing a pipeline on a water pipe seat 32, and fixing a lifting appliance and a lifting lug 33 of a crane 50;

when the crane is not hoisted, the beam 31 is clamped in the bellmouth 221, the pressure sensor 231 on the bellmouth 221 detects the stress distribution condition on the beam 31 in real time and sends the stress distribution condition to the control device 10 through the wireless transceiver 24, after the control device 10 processes data, if the data is abnormal, an instruction is sent out to enable the crane 50 to be incapable of working, and a worker can adjust the stress on the beam 31 by observing the display data on the control device 10;

during hoisting, a worker operates the control device 10 to control the crane 50 through the cable 51, at the moment, the distance sensor 232 on the socket 221 sends distance information to the control device 10 through the wireless transceiver 24, the control device 10 processes the data, if the data is abnormal, the worker sends a command to stop the crane 50, the worker can adjust the crane 50 after the crane 50 stops working, and the control device 10 is operated to continue working after the adjustment is finished;

after the crane 50 and the lifting appliance thereof are lifted in place, the beam 31 is clamped by the rack 42 and cannot fall down, and then the locking screw 43 is rotated to enable the locking screw 43 to press the rack 42, so that the safety is further improved.

In the description of the present invention, it is to be understood that the terms "coaxial", "bottom", "one end", "top", "middle", "other end", "upper", "one side", "top", "inner", "front", "center", "both ends", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

In the present invention, unless otherwise explicitly specified or limited, the terms "mounted," "disposed," "connected," "fixed," "screwed" and the like are to be construed broadly, e.g., as a fixed connection, a detachable connection, or an integral part; can be mechanically or electrically connected; the term "connected" may refer to a direct connection, an indirect connection through an intermediate, a connection between two elements or an interaction relationship between two elements, and unless otherwise specifically defined, the term should be understood as having a specific meaning in the present application by those skilled in the art.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a computer lab pipe section hoist and mount strutting arrangement which characterized in that: the device comprises a control device (10), a hanging beam device (30), a crane (50), two guide supporting devices (40) and two supporting seats (20), wherein the two guide supporting devices (40) are vertically arranged on the ground, the hanging beam device (30) is arranged between the two guide supporting devices (40), and the two supporting seats (20) are arranged on the ground below the hanging beam device (30);

the hanging beam device (30) comprises a cross beam (31), at least two water pipe seats (32) are fixedly mounted at the top of the cross beam (31), guide plates (34) are fixedly mounted at two ends of the cross beam (31) respectively, two rectangular grooves (341) are longitudinally formed in the plate body of each guide plate (34) close to two sides, each guide support device (40) comprises a support column (41), each support column (41) is hollow, two longitudinal racks (42) are embedded in one side of each support column (41) close to the hanging beam device (30), the positions of the two racks (42) correspond to the two rectangular grooves (341), the bottoms of the racks (42) are hinged to the support columns (41), a plurality of springs (44) are arranged between the inner walls of the racks (42) and the support columns (41), and two ends of each spring (44) are fixedly connected with the racks (42) and the support columns (41) respectively, the rack (42) comprises tooth parts (421) and flat parts (422), the tooth parts (421) are longitudinally arranged at intervals, the flat parts (422) are arranged between two adjacent tooth parts (421), and the top end surfaces of the tooth parts (421) are horizontal;

the supporting seat (20) comprises a bottom plate (21), a column body (22) and a wireless transceiver (24), the column body (22) is fixedly installed at the top of the bottom plate (21), a socket (221) is formed in the top of the column body (22), the socket (221) is matched with the cross beam (31), a sensor device (23) is arranged at the bottom of the socket (221), the sensor device (23) is in communication connection with the control device (10) through the wireless transceiver (24), and the control device (10) is in communication connection with the crane (50) through a cable (51).

2. The machine room pipe section hoisting and supporting device according to claim 1, characterized in that: one side, far away from the hanging beam device (30), of the supporting column (41) is provided with two rows of locking screws (43) which are longitudinally arranged, the positions of the two rows of locking screws (43) correspond to the positions of two longitudinally arranged racks (42), one end of each locking screw (43) is transversely inserted into the supporting column (41) and props against the racks (42), and the locking screws (43) are in threaded connection with the supporting column (41).

3. The machine room pipe section hoisting and supporting device according to claim 1, characterized in that: lifting lugs (33) are fixedly mounted at the top of the cross beam (31) close to the two ends respectively.

4. The machine room pipe section hoisting and supporting device according to claim 1, characterized in that: the number of the springs (44) is at least three, and the springs (44) are arranged at intervals in the longitudinal direction.

5. The machine room pipe section hoisting and supporting device according to claim 1, characterized in that: the sensor device (23) comprises a pressure sensor (231) and a distance sensor (232), the pressure sensor (231) and the distance sensor (232) are both arranged at the bottom of a socket (221) on the column body (22), and the sensor device (23) comprises a pressure sensor (231) which is in communication connection with the control device (10) through a wireless transceiver (24).

6. The machine room pipe section hoisting and supporting device according to claim 2, characterized in that: the number of locking screws (43) in each row is at least three.

Images