CN107324125B - Building cable pay-off rack - Google Patents

Abstract

The invention discloses a building cable pay-off rack which comprises an underframe, a bottom plate, supporting rods and a rack, wherein the bottom plate is arranged in the middle of the underframe, the bottom plate is welded with the underframe, the rack is arranged on the bottom plate, the rack is fixedly connected with the bottom plate, a sliding rail is arranged on the rack, the supporting rods are arranged on two sides of the sliding rail, the supporting rods are respectively fixedly connected with the underframe and the sliding rail, a hydraulic cylinder is arranged in the middle of the bottom plate, the hydraulic cylinder is provided with a telescopic rod, a sliding plate is arranged in the sliding rail, the telescopic rod is connected with the sliding plate, a bearing is arranged on the sliding plate, and the bearing is connected with the sliding plate in a clamping manner.

Description

Building cable pay-off rack

Technical Field

The invention relates to a building cable pay-off rack.

Background

The building is made of clay, bricks, tiles, stones and wood for people; (reinforced concrete and section bars are used recently) and other building materials, such as houses, bridges, plants, gymnasiums, cave dwellings, water towers, temples and the like. In a broad sense, landscapes and gardens are also part of buildings. More broadly, nests that are intentionally created by animals may also be counted as buildings. The west philosophy has clouds: the building is a set music, and the building is a stone history book. The classic name of ancient Roman architecture, Vitrelwei, is "architecture ten books" which proposes three standards of architecture: firm, practical and beautiful, and always influences the development of the future architects.

Cable payoff stands are also referred to as cable spool stands, wire spool stands, cable payoff stands, and the like, depending on the application. Cable payoff stands are also referred to as cable spool stands, wire spool stands, cable payoff stands, and the like, depending on the application. The lifting type cable pay-off rack can be divided into a hydraulic cable pay-off rack and a mechanical cable pay-off rack. The adjustable hydraulic pay-off rack is divided into an adjustable hydraulic pay-off rack, a column type pay-off rack, a push rod type cable pay-off rack, a horizontal cable wire coil rack, a foot brake cable pay-off rack, a detachable cable pay-off rack and a tension pay-off rack according to purposes and structural forms. The method is divided into the following steps according to the load capacity: 3T cable pay-off rack, 5T cable pay-off rack, 10T cable pay-off rack, 15T cable reel support, 20T cable reel support and cable reel pay-off support of greater tonnage. The applicable cable drum diameter scope of cable drum support does: 600mm-3800mm the user can select a suitable cable pay-off rack according to the diameter and tonnage of the cable reel. The static disc pay-off rack can be generally divided into a ground cable pulley, a skyward pulley, a nylon pulley, a cable wire pay-off pulley, a large-diameter pay-off pulley, a dual-purpose pay-off pulley for hanging, a ground wire pay-off pulley, a hoisting pulley and the like. The static disc pay-off rack is mainly used for playing a role in protecting when laying cable conductors, and is time-saving and labor-saving.

The height of the existing cable pay-off rack is not easy to adjust, and the structure of a telescopic rod is not adopted.

Disclosure of Invention

The invention aims to provide a building cable pay-off rack which is easy to adjust the height, adopts a telescopic rod, is corrosion-resistant, has high structural strength and is light in weight.

In order to solve the problems, the invention adopts the following technical scheme:

the utility model provides a building cable pay-off rack, includes chassis, bottom plate, bracing piece and frame, the bottom plate is established at the chassis middle part, bottom plate and chassis welding, the frame is established on the bottom plate, frame and bottom plate fixed connection, install the slide rail in the frame, the bracing piece is established in the slide rail both sides, the bracing piece respectively with chassis and slide rail fixed connection, the bottom plate mid-mounting has the pneumatic cylinder, the pneumatic cylinder is provided with the telescopic link, install the slide in the slide rail, the telescopic link is connected with the slide, install the bearing on the slide, the bearing is held with the slide card and is connected.

Preferably, the supporting rods are arranged at an inclination angle of 60 degrees, so that the supporting effect is good, and the structural stability is high.

Preferably, the slide rail is welded with the frame, so that the slide rail is firmly installed.

Preferably, the sliding plate is movably connected with the sliding rail, and the sliding plate is convenient and reliable to move.

Preferably, the number of the bearings is three, so that the cable can conveniently pass through the bearings to perform paying-off operation.

The building cable pay-off rack is characterized in that the telescopic rod is made of the following materials in parts by weight: 10-15 parts of polyvinylidene fluoride, 7-8 parts of aluminum hydroxide, 30-35 parts of phosphite, 7-15 parts of alkyd resin, 2-7 parts of ethoxyquinoline, 6-8 parts of polyacrylonitrile-based carbon fiber, 9-15 parts of heliotropin, 4-8 parts of salicylate, 22-25 parts of mercaptoacid ester, 3-9 parts of lithopone, 10-17 parts of white carbon black, 6-9 parts of magnesite gel, 11-14 parts of alkylolamide borate, 2-4 parts of p-nitrosodimethylaniline and 7-8 parts of tetrahydroisoquinoline.

The preparation method of the telescopic rod comprises the following steps:

1) putting 10-15 parts of polyvinylidene fluoride, 7-8 parts of aluminum hydroxide, 30-35 parts of phosphite, 7-15 parts of alkyd resin, 2-7 parts of ethoxyquinoline, 6-8 parts of polyacrylonitrile-based carbon fiber, 9-15 parts of heliotropin, 4-8 parts of salicylate, 22-25 parts of mercaptoacid ester, 3-9 parts of lithopone, 10-17 parts of white carbon black, 6-9 parts of magnesite gel, 11-14 parts of alkylolamide borate, 2-4 parts of p-nitrosodimethylaniline and 7-8 parts of tetrahydroisoquinoline into an oil bath pan, and preheating at 55 ℃ for later use;

2) mixing 0.2% sulfuric acid solution in the raw material obtained in the step 1), and stirring the raw material and the sulfuric acid solution according to the mass ratio of 35:1 for later use;

3) putting the raw materials obtained in the step 2) into a reaction kettle, adjusting the heating temperature to be 105-;

4) putting the raw materials obtained in the step 3) into a screw feeder, and heating the raw materials to be in a molten state for later use;

5) and (3) putting the raw materials obtained in the step 4) into a blow molding machine, and carrying out blow molding on the raw materials in a mold by the blow molding machine to obtain a hollow rod body.

The invention has the beneficial effects that: the chassis, the bottom plate, the support rod and the rack are compact in structure and good in structural stability; the telescopic rod is arranged on the hydraulic cylinder, so that the height of the sliding plate can be conveniently adjusted, and the hydraulic cylinder is suitable for paying-off operation in different environments; the bearing that sets up can make things convenient for penetrating of cable, and cable position is stable when keeping the unwrapping wire, and convenient operation adopts the telescopic rod material structure corrosion-resistant, long service life to adopt hollow structure, lighter for current metal material weight.

Drawings

Fig. 1 is a structural view of a construction cable reel according to the present invention.

Detailed Description

Example 1

As shown in fig. 1, a building cable pay-off rack, including chassis 1, bottom plate 2, bracing piece 3 and frame 4, bottom plate 2 is established at 1 middle part of chassis, bottom plate 2 and 1 welding of chassis, frame 4 is established on bottom plate 2, frame 4 and 2 fixed connection of bottom plate, install slide rail 5 in the frame 4, bracing piece 3 is established in 5 both sides of slide rail, bracing piece 3 respectively with chassis 1 and 5 fixed connection of slide rail, 2 mid-mounting of bottom plate have pneumatic cylinder 6, pneumatic cylinder 6 is provided with telescopic link 7, install slide 8 in the slide rail 5, telescopic link 7 is connected with slide 8, install bearing 9 on the slide 8, bearing 9 is held with slide 8 card and is connected.

The support rods 3 are arranged at an inclination angle of 60 degrees.

The sliding rail 5 is welded with the frame 4.

The sliding plate 8 is movably connected with the sliding rail 5.

The number of the bearings 9 is three.

The building cable pay-off rack is characterized in that the telescopic rod is made of the following materials in parts by weight: 10 parts of polyvinylidene fluoride, 7 parts of aluminum hydroxide, 30 parts of phosphite, 7 parts of alkyd resin, 2 parts of ethoxyquinoline, 6 parts of polyacrylonitrile-based carbon fiber, 9 parts of heliotropin, 4 parts of salicylate, 22 parts of mercapto acid ester, 3 parts of lithopone, 10 parts of white carbon black, 6 parts of magnesite gel, 11 parts of alkylolamide borate, 2 parts of p-nitrosoxylidine and 7 parts of tetrahydroisoquinoline.

The preparation method of the telescopic rod comprises the following steps:

1) putting 10 parts of polyvinylidene fluoride, 7 parts of aluminum hydroxide, 30 parts of phosphite, 7 parts of alkyd resin, 2 parts of ethoxyquinoline, 6 parts of polyacrylonitrile-based carbon fiber, 9 parts of heliotropin, 4 parts of salicylate, 22 parts of mercaptoacid ester, 3 parts of lithopone, 10 parts of white carbon black, 6 parts of magnesite gel, 11 parts of alkylolamide borate, 2 parts of p-nitrosodimethylaniline and 7 parts of tetrahydroisoquinoline into an oil bath pan, and preheating at 55 ℃ for later use;

2) mixing 0.2% sulfuric acid solution in the raw material obtained in the step 1), and stirring the raw material and the sulfuric acid solution according to the mass ratio of 35:1 for later use;

3) putting the raw materials obtained in the step 2) into a reaction kettle, adjusting the heating temperature to be 105-;

4) putting the raw materials obtained in the step 3) into a screw feeder, and heating the raw materials to be in a molten state for later use;

5) and (3) putting the raw materials obtained in the step 4) into a blow molding machine, and carrying out blow molding on the raw materials in a mold by the blow molding machine to obtain a hollow rod body.

Example 2

As shown in fig. 1, a building cable pay-off rack, including chassis 1, bottom plate 2, bracing piece 3 and frame 4, bottom plate 2 is established at 1 middle part of chassis, bottom plate 2 and 1 welding of chassis, frame 4 is established on bottom plate 2, frame 4 and 2 fixed connection of bottom plate, install slide rail 5 in the frame 4, bracing piece 3 is established in 5 both sides of slide rail, bracing piece 3 respectively with chassis 1 and 5 fixed connection of slide rail, 2 mid-mounting of bottom plate have pneumatic cylinder 6, pneumatic cylinder 6 is provided with telescopic link 7, install slide 8 in the slide rail 5, telescopic link 7 is connected with slide 8, install bearing 9 on the slide 8, bearing 9 is held with slide 8 card and is connected.

The support rods 3 are arranged at an inclination angle of 60 degrees.

The sliding rail 5 is welded with the frame 4.

The sliding plate 8 is movably connected with the sliding rail 5.

The number of the bearings 9 is three.

The building cable pay-off rack is characterized in that the telescopic rod is made of the following materials in parts by weight: 12.5 parts of polyvinylidene fluoride, 7.5 parts of aluminum hydroxide, 32.5 parts of phosphite, 11 parts of alkyd resin, 3.5 parts of ethoxyquinoline, 7 parts of polyacrylonitrile-based carbon fiber, 12 parts of heliotropin, 6 parts of salicylate, 23.5 parts of mercapto-acid ester, 6 parts of lithopone, 13.5 parts of white carbon black, 7.5 parts of magnesite gel, 12.5 parts of alkylolamide borate, 3 parts of p-nitrosoxylidine and 7.5 parts of tetrahydroisoquinoline.

The preparation method of the telescopic rod comprises the following steps:

1) putting 12.5 parts of polyvinylidene fluoride, 7.5 parts of aluminum hydroxide, 32.5 parts of phosphite, 11 parts of alkyd resin, 3.5 parts of ethoxyquinoline, 7 parts of polyacrylonitrile-based carbon fiber, 12 parts of heliotropin, 6 parts of salicylate, 23.5 parts of mercapto acid ester, 6 parts of lithopone, 13.5 parts of white carbon black, 7.5 parts of magnesite gel, 12.5 parts of alkylolamide borate, 3 parts of p-nitrosodimethylaniline and 7.5 parts of tetrahydroisoquinoline into an oil bath kettle, and preheating at 55 ℃ for later use;

2) mixing 0.2% sulfuric acid solution in the raw material obtained in the step 1), and stirring the raw material and the sulfuric acid solution according to the mass ratio of 35:1 for later use;

3) putting the raw materials obtained in the step 2) into a reaction kettle, adjusting the heating temperature to be 105-;

4) putting the raw materials obtained in the step 3) into a screw feeder, and heating the raw materials to be in a molten state for later use;

5) and (3) putting the raw materials obtained in the step 4) into a blow molding machine, and carrying out blow molding on the raw materials in a mold by the blow molding machine to obtain a hollow rod body.

Example 3

As shown in fig. 1, a building cable pay-off rack, including chassis 1, bottom plate 2, bracing piece 3 and frame 4, bottom plate 2 is established at 1 middle part of chassis, bottom plate 2 and 1 welding of chassis, frame 4 is established on bottom plate 2, frame 4 and 2 fixed connection of bottom plate, install slide rail 5 in the frame 4, bracing piece 3 is established in 5 both sides of slide rail, bracing piece 3 respectively with chassis 1 and 5 fixed connection of slide rail, 2 mid-mounting of bottom plate have pneumatic cylinder 6, pneumatic cylinder 6 is provided with telescopic link 7, install slide 8 in the slide rail 5, telescopic link 7 is connected with slide 8, install bearing 9 on the slide 8, bearing 9 is held with slide 8 card and is connected.

The support rods 3 are arranged at an inclination angle of 60 degrees.

The sliding rail 5 is welded with the frame 4.

The sliding plate 8 is movably connected with the sliding rail 5.

The number of the bearings 9 is three.

The building cable pay-off rack is characterized in that the telescopic rod is made of the following materials in parts by weight: 15 parts of polyvinylidene fluoride, 8 parts of aluminum hydroxide, 35 parts of phosphite, 15 parts of alkyd resin, 7 parts of ethoxyquinoline, 8 parts of polyacrylonitrile-based carbon fiber, 15 parts of heliotropin, 8 parts of salicylate, 25 parts of mercapto acid ester, 9 parts of lithopone, 17 parts of white carbon black, 9 parts of magnesite gel, 14 parts of alkylolamide borate, 4 parts of p-nitrosoxylidine and 8 parts of tetrahydroisoquinoline.

The preparation method of the telescopic rod comprises the following steps:

1) putting 15 parts of polyvinylidene fluoride, 8 parts of aluminum hydroxide, 35 parts of phosphite, 15 parts of alkyd resin, 7 parts of ethoxyquinoline, 8 parts of polyacrylonitrile-based carbon fiber, 15 parts of heliotropin, 8 parts of salicylate, 25 parts of mercapto acid ester, 9 parts of lithopone, 17 parts of white carbon black, 9 parts of magnesite gel, 14 parts of alkylolamide borate, 4 parts of p-nitrosodimethylaniline and 8 parts of tetrahydroisoquinoline into an oil bath, and preheating at 55 ℃ for later use;

2) mixing 0.2% sulfuric acid solution in the raw material obtained in the step 1), and stirring the raw material and the sulfuric acid solution according to the mass ratio of 35:1 for later use;

3) putting the raw materials obtained in the step 2) into a reaction kettle, adjusting the heating temperature to be 105-;

4) putting the raw materials obtained in the step 3) into a screw feeder, and heating the raw materials to be in a molten state for later use;

5) and (3) putting the raw materials obtained in the step 4) into a blow molding machine, and carrying out blow molding on the raw materials in a mold by the blow molding machine to obtain a hollow rod body.

Examples of the experiments

Subject: and selecting a common supporting rod, a special supporting rod and the supporting rod of the invention for test comparison.

The experimental requirements are as follows: the common support rod, the special support rod and the support rod of the invention are detected by adopting the same length and diameter.

The experimental method comprises the following steps: carrying out corrosion resistance detection on the supporting rod, detecting through a corrosion test box, and adjusting the temperature of the detection to be 120 ℃, the relative humidity to be 85%, the air pressure to be 106kPa, the ozone concentration to be 45% and the ultraviolet illumination intensity to be 25uw/cm2 to obtain the corrosion time; detecting the density by a density detector; the compressive strength is detected by adopting a GBT228-2002 method.

The test data are as follows:

by combining the above table and comparing the data obtained by different support rods under the same experimental method, the support rod structure of the invention has higher strength, lower density and better corrosion resistance.

The invention has the beneficial effects that: the chassis, the bottom plate, the support rod and the rack are compact in structure and good in structural stability; the telescopic rod is arranged on the hydraulic cylinder, so that the height of the sliding plate can be conveniently adjusted, and the hydraulic cylinder is suitable for paying-off operation in different environments; the bearing that sets up can make things convenient for penetrating of cable, and cable position is stable when keeping the unwrapping wire, and convenient operation adopts the telescopic rod material structure corrosion-resistant, long service life to adopt hollow structure, lighter for current metal material weight.

The above description is only an embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that are not thought of through the inventive work should be included in the scope of the present invention.

Claims (1)

1. The utility model provides a building cable pay off rack which characterized in that: the lifting rod of the building cable pay-off rack is prepared from the following materials in parts by weight: 10-15 parts of polyvinylidene fluoride, 7-8 parts of aluminum hydroxide, 30-35 parts of phosphite, 7-15 parts of alkyd resin, 2-7 parts of ethoxyquinoline, 6-8 parts of polyacrylonitrile-based carbon fiber, 9-15 parts of heliotropin, 4-8 parts of salicylate, 22-25 parts of mercaptoacid ester, 3-9 parts of lithopone, 10-17 parts of white carbon black, 6-9 parts of magnesite gel, 11-14 parts of alkylolamide borate, 2-4 parts of p-nitrosodimethylaniline and 7-8 parts of tetrahydroisoquinoline, wherein the preparation method of the telescopic rod comprises the following steps:

1) putting 10-15 parts of polyvinylidene fluoride, 7-8 parts of aluminum hydroxide, 30-35 parts of phosphite, 7-15 parts of alkyd resin, 2-7 parts of ethoxyquinoline, 6-8 parts of polyacrylonitrile-based carbon fiber, 9-15 parts of heliotropin, 4-8 parts of salicylate, 22-25 parts of mercaptoacid ester, 3-9 parts of lithopone, 10-17 parts of white carbon black, 6-9 parts of magnesite gel, 11-14 parts of alkylolamide borate, 2-4 parts of p-nitrosodimethylaniline and 7-8 parts of tetrahydroisoquinoline into an oil bath pan, and preheating at 55 ℃ for later use;

2) mixing 0.2% sulfuric acid solution in the raw material obtained in the step 1), and stirring the raw material and the sulfuric acid solution according to the mass ratio of 35:1 for later use;

3) putting the raw materials obtained in the step 2) into a reaction kettle, adjusting the heating temperature to be 105-;

4) putting the raw materials obtained in the step 3) into a screw feeder, and heating the raw materials to be in a molten state for later use;

5) and (3) putting the raw materials obtained in the step 4) into a blow molding machine, and carrying out blow molding on the raw materials in a mold by the blow molding machine to obtain a hollow rod body.

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