CN219102403U - Anti-seismic design structure of anti-corrosion heat-insulation pipe - Google Patents
Anti-seismic design structure of anti-corrosion heat-insulation pipe Download PDFInfo
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- CN219102403U CN219102403U CN202222572329.8U CN202222572329U CN219102403U CN 219102403 U CN219102403 U CN 219102403U CN 202222572329 U CN202222572329 U CN 202222572329U CN 219102403 U CN219102403 U CN 219102403U
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Abstract
The utility model discloses an anti-seismic design structure of an anti-corrosion heat-insulation pipe, and relates to the technical field of heat-insulation pipes. Including bottom plate and annular plate, the bottom plate is placed on the wall, and all is provided with fixed establishment between bottom plate four corners department and the wall, bottom plate lateral wall both sides all are fixed with the hypoplastron, two be provided with the insulating tube between the hypoplastron, the annular plate cover is established outside the insulating tube, all be provided with buffer gear between annular plate both sides and the hypoplastron. According to the utility model, the heat-insulating pipe is subjected to earthquake resistance through the buffer mechanism, the heat-insulating pipe can be buffered through the telescopic rod when the wall is subjected to transverse vibration, the wall can be buffered through the vertical buffer mechanism when the wall is subjected to vertical vibration, and the heat-insulating pipe can be effectively subjected to earthquake resistance through the mutual matching of the telescopic rod and the vertical buffer mechanism.
Description
Technical Field
The utility model belongs to the technical field of heat preservation pipes, and particularly relates to an anti-seismic design structure of an anti-corrosion heat preservation pipe.
Background
The heat insulating pipe is used for conveying liquid, gas and other medium, and is used in heat insulating engineering for petroleum, chemical, spaceflight, hot spring, central heating, central air conditioner, city, etc. Some existing insulating pipes are installed on a wall through a bracket, when the wall vibrates, the insulating pipes can be taken to vibrate together, if the vibration amplitude of the insulating pipes is too large, the joints of the insulating pipes are broken, so that certain potential safety hazards are caused, the existing bracket is used for simply installing the insulating pipes on the wall and does not have an anti-vibration structure, and therefore, the anti-vibration design structure of the anti-corrosion insulating pipes is provided.
Disclosure of Invention
The utility model aims to provide an anti-seismic design structure of an anti-corrosion heat-insulation pipe, which solves the problem that the joint of the heat-insulation pipe is broken if the vibration amplitude of the heat-insulation pipe is too large through a buffer mechanism.
In order to solve the technical problems, the utility model is realized by the following technical scheme:
the utility model relates to an anti-seismic design structure of an anti-corrosion heat-insulation pipe, which comprises a bottom plate and annular plates, wherein the bottom plate is placed on a wall, fixing mechanisms are arranged between four corners of the bottom plate and the wall, lower plates are fixed on two sides of the side wall of the bottom plate, a heat-insulation pipe is arranged between the two lower plates, the annular plates are sleeved outside the heat-insulation pipe, and buffer mechanisms are arranged between the two sides of the annular plates and the lower plates.
Further, the fixing mechanism comprises mounting holes and bolts, the mounting holes are formed in four corners of the bottom plate, and one ends of the bolts penetrate through the mounting holes and are fixed in the wall.
Further, buffer gear includes two curb plates and connecting plate, two the curb plate is fixed in annular plate lateral wall both sides, the connecting plate sets up between annular plate and hypoplastron, be provided with vertical buffer gear between connecting plate lateral wall and the hypoplastron, all be fixed with the telescopic link between another lateral wall both sides of connecting plate and the two curb plates.
Further, vertical buffer gear includes slide and slide hole, the slide hole is seted up in hypoplastron one side, the slide is fixed at the connecting plate lateral wall, the slide slides and sets up in the slide hole, slide hole lateral wall both sides all are fixed with the slide bar, slide bar one end passes the slide and fixes at slide hole another lateral wall, two slide bar one side all overlaps and is equipped with the side spring, side spring one end is fixed on the slide, the side spring other end is fixed at the slide hole lateral wall.
Further, the telescopic link includes sleeve pipe and side lever, the sleeve pipe is fixed at the connecting plate lateral wall, side lever one end is fixed at the curb plate lateral wall, the side lever other end inserts and establishes at the intraductal, and the side lever other end is fixed with the pole limiting plate, pole limiting plate one side is fixed with the spring, spring one end is fixed in the intraductal bottom of sleeve.
Further, an annular rubber pad is fixed on the inner wall of the annular plate.
The utility model has the following beneficial effects:
according to the utility model, the heat-insulating pipe is subjected to earthquake resistance through the buffer mechanism, the wall can be buffered through the telescopic rod when the wall is subjected to transverse vibration, the wall can be buffered through the vertical buffer mechanism when the wall is subjected to vertical vibration, and the heat-insulating pipe can be effectively subjected to earthquake resistance through the mutual matching of the telescopic rod and the vertical buffer mechanism.
Of course, it is not necessary for any one product to practice the utility model to achieve all of the advantages set forth above at the same time.
Drawings
In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed for the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.
FIG. 1 is a schematic perspective view of an anti-seismic design of an anti-corrosive insulating pipe;
FIG. 2 is a schematic diagram of a front view of an earthquake-resistant design of an anti-corrosive insulating pipe;
FIG. 3 is a schematic side view of an earthquake-resistant design of an anti-corrosive thermal insulation pipe;
FIG. 4 is a schematic view of a telescopic rod of an anti-seismic design of an anti-corrosive thermal insulation pipe;
in the drawings, the list of components represented by the various numbers is as follows:
1. a bottom plate; 2. a lower plate; 3. a connecting plate; 4. an annular plate; 5. a side plate; 6. a telescopic rod; 61. a sleeve; 62. a side bar; 63. a rod limiting plate; 64. a spring; 7. an annular rubber pad; 8. a slide plate; 9. a slide hole; 10. a slide bar; 11. a side spring; 12. a mounting hole; 13. and (5) a bolt.
Detailed Description
The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.
Referring to fig. 1-4, the utility model discloses an anti-vibration design structure of an anti-vibration heat-insulating pipe, which comprises a bottom plate 1 and annular plates 4, wherein the bottom plate 1 is placed on a wall, fixing mechanisms are arranged between four corners of the bottom plate 1 and the wall, lower plates 2 are fixed on two sides of the side wall of the bottom plate 1, a heat-insulating pipe is arranged between the two lower plates 2, the annular plates 4 are sleeved outside the heat-insulating pipe, the outer wall of the heat-insulating pipe is made of polyurethane materials, the polyurethane heat-insulating pipe is formed by foaming a high-functional polyether polyol combination material and a multi-methyl polyphenyl polyisocyanate through chemical reaction, the polyurethane heat-insulating pipe has the excellent characteristics of light volume weight, high strength, heat insulation, sound insulation, flame retardance, cold resistance, corrosion resistance, no water absorption, simplicity, rapidness in construction and the like, the inner wall of the annular plates 4 is fixed with annular rubber pads 7, the heat-insulating pipe can be placed in the annular plates 4 more stably, the annular rubber pads 7 have a certain buffer effect, and the buffer mechanisms are arranged between the two sides of the annular plates 4 and the lower plates 2, and the heat-insulating pipe can be subjected to anti-vibration treatment through the buffer mechanism when vibration occurs on the wall.
As shown in fig. 1-3, the fixing mechanism comprises mounting holes 12 and bolts 13, the mounting holes 12 are formed in four corners of the base plate 1, one ends of the bolts 13 penetrate through the mounting holes 12 and are fixed in the wall, and the base plate 1 can be fixed on the wall through polyurethane.
As shown in fig. 1-4, the buffer mechanism comprises two side plates 5 and a connecting plate 3, the two side plates 5 are fixed on two sides of the side wall of the annular plate 4, the connecting plate 3 is arranged between the annular plate 4 and the lower plate 2, a vertical buffer mechanism is arranged between the side wall of the connecting plate 3 and the lower plate 2, telescopic rods 6 are fixed between two sides of the other side wall of the connecting plate 3 and the two side plates 5, each telescopic rod 6 comprises a sleeve 61 and a side rod 62, the sleeve 61 is fixed on the side wall of the connecting plate 3, one end of each side rod 62 is fixed on the side wall of the side plate 5, the other end of each side rod 62 is inserted into the sleeve 61, the other end of each side rod 62 is fixed with a rod limiting plate 63, one side of each rod limiting plate 63 is fixed with a spring 64, one end of each spring 64 is fixed on the inner bottom of the sleeve 61, when the wall vibrates transversely, the side rod 62 moves in the sleeve 61, the springs 64 deform, the springs 64 can prolong the acting time of force, and the force exerted by the side rods under the same momentum change, the force is reduced, so that the shock absorption buffer effect is achieved.
As shown in fig. 1-3, the vertical buffering mechanism comprises a sliding plate 8 and a sliding hole 9, the sliding hole 9 is formed in one side of the lower plate 2, the sliding plate 8 is fixed on the side wall of the connecting plate 3, the sliding plate 8 is arranged in the sliding hole 9 in a sliding mode, sliding rods 10 are respectively fixed on two sides of the side wall of the sliding hole 9, one end of each sliding rod 10 penetrates through the sliding plate 8 and is fixed on the other side wall of the sliding hole 9, side springs 11 are respectively sleeved on one sides of the two sliding rods 10, one end of each side spring 11 is fixed on the sliding plate 8, the other ends of the side springs 11 are fixed on the side wall of the sliding hole 9, when the wall vibrates vertically, the sliding plate 8 slides on the sliding rods 10, at the moment, the side springs 11 deform, the time of force acting can be prolonged, and the force exerted on an object is reduced under the same momentum change, so that the effects of damping and buffering are achieved.
One specific application of this embodiment is: can install the device on the wall through fixed establishment, can just carry out buffer treatment to it through telescopic link 6 when the wall takes place horizontal vibrations, when the wall takes place vertical vibrations, just can carry out buffer treatment to it through vertical buffer gear, just can effectually carry out shock-resistant treatment to the insulating tube through telescopic link 6 and vertical buffer gear mutually support.
In the description of the present specification, the descriptions of the terms "one embodiment," "example," "specific example," and the like, mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present utility model. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.
The preferred embodiments of the utility model disclosed above are intended only to assist in the explanation of the utility model. The preferred embodiments are not exhaustive or to limit the utility model to the precise form disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the utility model and the practical application, to thereby enable others skilled in the art to best understand and utilize the utility model. The utility model is limited only by the claims and the full scope and equivalents thereof.
Claims (6)
1. The utility model provides an antidetonation design structure of anticorrosive insulating tube, includes bottom plate (1) and annular plate (4), bottom plate (1) are placed on the wall, and all are provided with fixed establishment between bottom plate (1) four corners department and the wall, its characterized in that: the utility model discloses a thermal insulation device, including bottom plate (1), annular board (4), buffer gear, lower board (2) are all fixed with in bottom plate (1) lateral wall both sides, two be provided with the insulating tube between lower board (2), annular board (4) cover is established outside the insulating tube, all be provided with buffer gear between annular board (4) both sides and lower board (2).
2. The anti-seismic design structure of the anti-corrosion heat preservation pipe according to claim 1, wherein the fixing mechanism comprises mounting holes (12) and bolts (13), the mounting holes (12) are formed in four corners of the bottom plate (1), and one ends of the bolts (13) penetrate through the mounting holes (12) and are fixed in a wall.
3. The anti-seismic design structure of an anti-corrosion heat-insulation pipe according to claim 1, wherein the buffer mechanism comprises two side plates (5) and a connecting plate (3), the two side plates (5) are fixed on two sides of the side wall of the annular plate (4), the connecting plate (3) is arranged between the annular plate (4) and the lower plate (2), a vertical buffer mechanism is arranged between the side wall of the connecting plate (3) and the lower plate (2), and telescopic rods (6) are fixed between two sides of the other side wall of the connecting plate (3) and the two side plates (5).
4. The anti-seismic design structure of an anti-corrosion heat-insulation pipe according to claim 3, wherein the vertical buffer mechanism comprises a sliding plate (8) and sliding holes (9), the sliding holes (9) are formed in one side of a lower plate (2), the sliding plate (8) is fixed on the side wall of the connecting plate (3), the sliding plate (8) is arranged in the sliding holes (9) in a sliding manner, sliding rods (10) are fixed on two sides of the side wall of the sliding holes (9), one end of each sliding rod (10) penetrates through the sliding plate (8) and is fixed on the other side wall of the sliding hole (9), side springs (11) are sleeved on one sides of each sliding rod (10), one end of each side spring (11) is fixed on the sliding plate (8), and the other end of each side spring (11) is fixed on the side wall of the sliding hole (9).
5. A shock-resistant design structure of an anti-corrosion heat-insulating pipe according to claim 3, wherein the telescopic rod (6) comprises a sleeve (61) and a side rod (62), the sleeve (61) is fixed on the side wall of the connecting plate (3), one end of the side rod (62) is fixed on the side wall of the side plate (5), the other end of the side rod (62) is inserted into the sleeve (61), the other end of the side rod (62) is fixed with a rod limiting plate (63), one side of the rod limiting plate (63) is fixed with a spring (64), and one end of the spring (64) is fixed at the inner bottom of the sleeve (61).
6. The anti-seismic design structure of the anti-corrosion heat preservation pipe according to claim 1, wherein an annular rubber pad (7) is fixed on the inner wall of the annular plate (4).
Priority Applications (1)
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CN202222572329.8U CN219102403U (en) | 2022-09-28 | 2022-09-28 | Anti-seismic design structure of anti-corrosion heat-insulation pipe |
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CN202222572329.8U CN219102403U (en) | 2022-09-28 | 2022-09-28 | Anti-seismic design structure of anti-corrosion heat-insulation pipe |
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CN219102403U true CN219102403U (en) | 2023-05-30 |
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CN202222572329.8U Active CN219102403U (en) | 2022-09-28 | 2022-09-28 | Anti-seismic design structure of anti-corrosion heat-insulation pipe |
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