CN211425173U - Flexible pipe radiator based on fluoroplastic pipe - Google Patents

Abstract

The utility model provides a flexible pipe radiator based on fluoroplastic pipes, which comprises main radiating fins, terminal radiating fins, connecting ribs, a middle section grounding node and an independent fan; the center of the main radiating fin is provided with a circular hole, and four end points of two lines which are vertical to each other at the edge of the circular hole of the main radiating fin are connected to the connecting ribs through welding; the connecting ribs are connected with the main heat dissipation fins in a welding mode; the bottom of the middle end of the connecting rib is provided with a middle section grounding node through welding connection, and the center of the middle section grounding node is opened; the tail ends of the two ends of the connecting rib are connected with terminal radiating fins through welding; and the top end of the middle section grounding node is connected with and provided with an independent fan through a screw. The arrangement of the middle section grounding node and the terminal radiating fins solves the problems that when the existing radiator radiates heat to the fluoroplastic flexible pipe, the heat radiation area is divided in a subarea mode, and certain improvement space exists in the aspects of pipeline structure reinforcing support and three-dimensional heat radiation.

Description

Flexible pipe radiator based on fluoroplastic pipe

Technical Field

The utility model belongs to the technical field of the pipeline heat dissipation, more specifically say, in particular to flexible pipe radiator based on fluoroplastics pipe.

Background

The flexible pipe is a fire-resistant, corrosion-resistant and water-resistant pipeline. Due to the thermodynamic characteristics of the flexible pipe, the flexible pipe is often used as a high-temperature transportation pipeline, and in this case, in order to improve the transportation safety, a heat dissipation device is often required to be sleeved outside the flexible pipe.

The utility model discloses a thermal shock resistant seal formula radiator as application number 201820342811.3, the utility model discloses a thermal shock resistant seal formula radiator, including feed liquor room, liquid outlet chamber and gas channel and the liquid channel of separating into alternate arrangement by a plurality of baffles, the feed liquor room on be equipped with the feed liquor pipe, the liquid outlet chamber on be equipped with the drain pipe; each gas channel is enclosed by an upper layer of partition board, a lower layer of partition board and short seal strips at two ends, and a heat dissipation belt is arranged in each gas channel; each liquid channel is formed by enclosing an upper layer of partition plate, a lower layer of partition plate and long sealing strips on two sides, turbulence sheets are arranged in the liquid channel, two ends of the turbulence sheets are respectively communicated with the liquid inlet chamber and the liquid outlet chamber, and at least one through hole penetrating in the length direction is formed in each long sealing strip. The utility model discloses guaranteed that the area of weld of long strip of paper used for sealing and baffle does not reduce, increased the flexible strength of long strip of paper used for sealing and more reasonable transverse thermal expansion rate, reduced baffle and long strip of paper used for sealing juncture thermal stress, the effectual thermal shock life-span that has improved has reduced the weight of long strip of paper used for sealing simultaneously, makes the product lightweight, has reduced the use and the manufacturing cost of material.

Through the search in the above documents, we have found that the existing radiator structure is used for radiating heat for fluoroplastic flexible pipes. Often adopt comparatively single average heat radiation structure, different structures are made according to regional division to the not fine heat dissipation needs that adapt to the difference of pipeline different positions that do not, for example, two terminals of pipeline generally give out heat the biggest, at this moment, adopt the heat radiation structure the same with pipeline guan deep position just can not be fine satisfy this part great heat dissipation demand that gives out heat, pipeline central point puts for a long time simultaneously and makedly, central point atress is great at ordinary times, the pipeline is ageing easily, current radiator structure does not often have corresponding bearing structure to carry out certain support to the pipeline this part, and heat radiation structure generally is the heat radiation structure of single direction, in the nimble spatial structure that utilizes, utilize longitudinal structure and transverse structure to combine each other and carry out three-dimensional heat dissipation, there is the space of improving in the space utilization efficiency.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model provides a flexible tube radiator based on fluoroplastics pipe to solve current radiator when the heat dissipation to fluoroplastics flexible tube, at heat dissipation regional subregion division, there is the problem in certain improvement space in the aspect of pipeline structure reinforcing support and the three-dimensional heat dissipation.

The utility model is achieved by the following concrete technical means:

the flexible pipe radiator based on the fluoroplastic pipe comprises main radiating fins, terminal radiating fins, connecting ribs, a middle section grounding node and an independent fan; the center of the main radiating fin is provided with a circular hole, and four end points of two lines which are vertical to each other at the edge of the circular hole of the main radiating fin are connected to the connecting ribs through welding; the connecting ribs are connected with the main heat dissipation fins in a welding mode; the bottom of the middle end of the connecting rib is provided with a middle section grounding node through welding connection, and the center of the middle section grounding node is opened; the tail ends of the two ends of the connecting rib are connected with terminal radiating fins through welding; and the top end of the middle section grounding node is connected with and provided with an independent fan through a screw.

Furthermore, auxiliary fins are welded and connected above the round holes on the front surface of the main heat dissipation fins; the radiating fins and the auxiliary fins are all of round-corner rectangular metal sheet structures; the auxiliary fins are perpendicular to the main heat dissipation fins, and each auxiliary fin is provided with a groove with three closed surfaces and one open surface.

Furthermore, the terminal radiating fin is of a long rectangular metal structure of the double-layer frame, and the area of the terminal radiating fin is larger than that of the main radiating fin; the outer ring of the terminal radiating fin is an aluminum alloy frame, the inner ring of the terminal radiating fin is a copper metal embedded sheet, and the copper metal embedded sheet of the terminal radiating fin is connected with the connecting rib in a welding mode.

Furthermore, the connecting ribs are of metal cylindrical frame structures, reinforcing circular ring nodes formed by annular metal frames are arranged at intervals on the connecting ribs, the outer walls of the circular ring nodes of the connecting ribs are connected with the outer annular frame of the inner contact point through welding, and the circular ring nodes fix the inner contact point; the inner contact points are bilaterally symmetrical along the circular ring node; the inner contact point is of a metal cylindrical structure, and consists of two metal radiating discs, a vertical ball and a metal ring frame; the metal ring frame of interior contact point cup joints metal cylinder structure, and the top and the bottom of metal cylinder structure install metal heat dissipation dish through welded connection, and the metal heat dissipation dish of bottom hangs through the cable and installs a plumb bob, and the metal heat dissipation dish bottom surface of bottom is the arc, and contacts with inside flexible pipe.

Further, a water injection cavity is arranged in the middle section grounding node and is a cooling cavity; the cooling cavity is integrally sealed and is symmetrical left and right; the counterweight plate is connected below the middle section grounding node in a welding manner, and the diameter of the middle section grounding node is smaller than that of the counterweight plate; the bottom of the counterweight plate is provided with a raised circumferential corrugated structure.

Furthermore, the independent fan is a cylindrical fan structure which is powered by four No. 5 batteries and is independent in switch.

Compared with the prior art, the utility model discloses following beneficial effect has:

the main radiating fins are used for bearing the main radiating function, the main radiating fins are in contact with the internal pipeline through the connecting ribs for heat exchange, the good heat conducting performance of metal and the area and the number of the radiating fins are used for heat dissipation, meanwhile, on the basis, the auxiliary fins are used for further improving the area of a radiating structure, and meanwhile, the radiating structure is more three-dimensional due to the design that the auxiliary fins are perpendicular to the main radiating fins.

The terminal radiating fins are responsible for the radiating requirements of the two terminals of the pipeline, and the radiating efficiency of the terminal nodes is improved by utilizing the larger area of the terminal radiating fins and the aluminum-copper double-layer structure.

Constitute pipeline structure and connect other heat radiation structure through the splice bar, and interior contact point on the splice bar increases the area of contact of splice bar and inside pipeline, wherein, the metal cylinder structure of interior contact point can be in the ring activity from top to bottom, and the arc metal heat dissipation dish of metal cylinder structure bottom directly contacts with inside fluoroplastics pipeline, the pipeline curved surface can be laminated more to the arc structure, metal overall structure who constitutes through metal heat dissipation dish and metal cylinder structure from top to bottom carries out the heat exchange to the pipeline, the area that utilizes the metal heat dissipation dish on top dispels the heat, utilize the structure of hanging down to increase bottom weight simultaneously, ensure metal heat dissipation dish and pipeline mutual contact.

The heat dissipation requirement of the middle-end part is charged through the middle-section grounding node, meanwhile, the metal structure of the counterweight plate of the middle-section grounding node plays a role in stabilizing the center of gravity of the whole structure, the sealed water in the cooling cavity can bear the heat absorption effect of a greater degree by utilizing the higher specific heat capacity of the water, the metal wrinkles of the counterweight plate at the bottom increase the surface area, and the heat dissipation efficiency is improved.

The air circulation near the whole structure is improved by the independent fan, and the heat exchange efficiency is improved in an auxiliary mode.

Drawings

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

Fig. 2 is a schematic diagram of the independent structure of the main heat dissipation fins of the present invention.

Fig. 3 is a schematic diagram of the structure of the inner contact point of the present invention.

Fig. 4 is the utility model discloses a middle section ground connection node structure schematic diagram.

Fig. 5 is a schematic view of the cross-sectional structure a-a of the present invention.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. a primary heat sink fin; 2. a terminal heat sink; 3. connecting ribs; 4. a middle section ground node; 5. an independent fan; 101. adjusting screws; 301. an inner contact point; 302. a drooping ball; 303. a metal heat dissipation plate; 401. a cooling chamber; 402. a counterweight plate.

Detailed Description

The following describes embodiments of the present invention in further detail with reference to the accompanying drawings and examples. The following examples are intended to illustrate the invention, but are not intended to limit the scope of the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are merely for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example (b):

as shown in figures 1 to 5:

the utility model provides a flexible pipe radiator based on fluoroplastic pipes, which comprises main radiating fins 1, terminal radiating fins 2, connecting ribs 3, a middle section grounding node 4 and an independent fan 5; the center of the main radiating fin 1 is provided with a circular hole, and four end points of two lines perpendicular to each other at the edge of the circular hole of the main radiating fin 1 are connected to the connecting rib 3 through welding; the connecting ribs 3 are connected with the main heat dissipation fins 1 through welding; the middle-end bottom of the connecting rib 3 is provided with a middle-section grounding node 4 through welding connection, and the center of the middle-section grounding node 4 is opened; the tail ends of the two ends of the connecting rib 3 are connected with terminal radiating fins 2 in a welding manner; and the top end of the middle section grounding node 4 is connected with and provided with an independent fan 5 through a screw.

The upper part of the round hole on the front surface of the main radiating fin 1 is provided with an auxiliary fin 101 through welding connection; the radiating fins 1 and the auxiliary fins 101 are both of round-corner rectangular sheet metal structures; the auxiliary fins 101 are perpendicular to the main heat dissipation fins 1, and the auxiliary fins 101 are provided with grooves with three closed surfaces and one open surface. Main heat dissipation function is undertaken through main heat dissipation fin 1, and main heat dissipation fin 1 contacts with the internal pipeline through splice bar 3 and carries out the heat exchange, utilizes the good heat conductivility of metal and the structure on area and the quantity of heat dissipation fin 1 to carry out the heat dissipation, simultaneously on this basis, utilizes vice fin 101 further to improve heat dissipation structure area, and the design of vice fin 101 and main heat dissipation fin 1 mutually perpendicular also makes heat radiation structure more three-dimensional simultaneously.

The terminal radiating fin 2 is of a strip rectangular metal structure with a double-layer frame, and the area of the terminal radiating fin 2 is larger than that of the main radiating fin 1; the outer ring of the terminal radiating fin 2 is an aluminum alloy frame, the inner ring of the terminal radiating fin 2 is a copper metal embedded sheet, and the copper metal embedded sheet of the terminal radiating fin 2 is connected with the connecting rib 3 in a welding mode. The terminal radiating fins 2 are used for meeting the radiating requirements of the two terminals of the pipeline, and the radiating efficiency of the terminal node is improved by utilizing the larger area of the terminal radiating fins 2 and the aluminum-copper double-layer structure.

The connecting ribs 3 are of a metal cylindrical frame structure, reinforcing circular ring nodes formed by annular metal frames are arranged at intervals on the connecting ribs 3, the outer walls of the circular ring nodes of the connecting ribs 3 are connected with the outer circular frame of the inner contact point 301 through welding, and the inner contact point 301 is fixed by the circular ring nodes; the inner contact points 301 are bilaterally symmetrical along a circular ring node; the inner contact point 301 is of a metal cylindrical structure, and consists of two metal radiating discs 303, a vertical ball 302 and a metal ring frame; the metal ring frame of the inner contact point 301 is sleeved with a metal cylindrical structure, the top end and the bottom end of the metal cylindrical structure are connected through welding to be provided with a metal heat dissipation disc 303, the metal heat dissipation disc 303 at the bottom end is provided with a vertical ball 302 in a hanging mode through a cable, and the bottom surface of the metal heat dissipation disc 303 at the bottom end is arc-shaped and is in contact with the inner flexible pipe. Constitute pipeline structure and connect other heat radiation structure through splice bar 3, and interior contact point 301 on splice bar 3 increases the area of contact of splice bar 3 and inner tube way, wherein, the metal cylinder structure of interior contact point 301 can be in the ring activity from top to bottom, and the arc metal heat dissipation dish 303 of metal cylinder structure bottom directly contacts with inside fluoroplastics pipeline, the pipeline curved surface can be laminated more to the arc structure, metal overall structure through metal heat dissipation dish 303 and metal cylinder structure constitution carries out the heat exchange to the pipeline from top to bottom, utilize the area of the metal heat dissipation dish 303 on top to dispel the heat, utilize the plumb bob 302 structure to increase bottom weight simultaneously, ensure metal heat dissipation dish 303 and pipeline mutual contact.

A water-filled cavity serving as a cooling cavity 401 is arranged inside the middle-section grounding node 4; the cooling cavity 401 is integrally sealed and is symmetrical left and right; the counterweight plate 402 is connected below the middle section grounding node 4 through welding, and the diameter of the middle section grounding node 4 is smaller than that of the counterweight plate 402; the bottom of the weight plate 402 has a raised circumferential corrugated structure. The middle section grounding node 4 is used for meeting the heat dissipation requirement of the middle end part, meanwhile, the metal structure of the counterweight plate 402 of the middle section grounding node 4 is used for stabilizing the center of gravity of the whole structure, the water sealed in the cooling cavity 401 can absorb heat to a greater extent by utilizing the higher specific heat capacity of the water, the metal wrinkles of the counterweight plate 402 at the bottom increase the surface area, and the heat dissipation efficiency is improved.

The independent fan 5 is a cylindrical fan structure which is powered by four No. 5 batteries and is independent in switch. The independent fan 5 improves the air circulation near the whole structure, and assists to improve the heat exchange efficiency.

The specific use mode and function of the embodiment are as follows:

in the utility model, when in use, the main heat dissipation fins 1 are used for bearing the main heat dissipation function, the main heat dissipation fins 1 are contacted with the internal pipeline through the connecting ribs 3 for heat exchange, the good heat conductivity of metal and the structures on the area and the quantity of the heat dissipation fins 1 are used for heat dissipation, meanwhile, on the basis, the auxiliary fins 101 are used for further improving the area of the heat dissipation structure, and meanwhile, the mutually vertical design of the auxiliary fins 101 and the main heat dissipation fins 1 also enables the heat dissipation structure to be more three-dimensional; the terminal radiating fins 2 are used for meeting the radiating requirements of two terminals of the pipeline, and the radiating efficiency of the terminal nodes is improved by utilizing the larger area of the terminal radiating fins 2 and the aluminum-copper double-layer structure; the pipeline structure is formed by the connecting ribs 3 and is connected with other heat dissipation structures, the contact area between the connecting ribs 3 and an internal pipeline is increased by the inner contact points 301 on the connecting ribs 3, wherein the metal cylindrical structures of the inner contact points 301 can move up and down in a circular ring, the arc-shaped metal heat dissipation discs 303 at the bottoms of the metal cylindrical structures are directly contacted with the internal fluoroplastic pipeline, the arc-shaped structures can be more attached to the curved surface of the pipeline, heat exchange is carried out on the pipeline through the metal integral structure formed by the upper metal heat dissipation discs 303, the area of the metal heat dissipation discs 303 at the top ends is utilized for heat dissipation, meanwhile, the weight of the bottom is increased by the aid of the drooping ball 302 structure, and the metal heat dissipation discs 303 are ensured; the middle-section grounding node 4 is used for meeting the heat dissipation requirement of the middle-end part, and meanwhile, the metal structure of the counterweight plate 402 of the middle-section grounding node 4 is used for stabilizing the gravity center of the whole structure, so that the water sealed in the cooling cavity 401 can bear a larger heat absorption effect by using higher specific heat capacity of the water, the metal wrinkles of the counterweight plate 402 at the bottom increase the surface area, and the heat dissipation efficiency is improved; the independent fan 5 improves the air circulation near the whole structure, and assists to improve the heat exchange efficiency.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (6)

1. A flexible pipe radiator based on a fluoroplastic pipe is characterized in that: the flexible pipe radiator based on the fluoroplastic pipe comprises main radiating fins (1), terminal radiating fins (2), connecting ribs (3), a middle section grounding node (4) and an independent fan (5); the center of the main heat dissipation fin (1) is provided with a circular hole, and four end points of two lines, which are perpendicular to each other, of the edge of the circular hole of the main heat dissipation fin (1) are connected to the connecting rib (3) through welding; the connecting ribs (3) are connected with the main heat dissipation fins (1) through welding; the middle-end bottom of the connecting rib (3) is provided with a middle-section grounding node (4) through welding connection, and the center of the middle-section grounding node (4) is opened; the tail ends of the two ends of the connecting rib (3) are connected with terminal radiating fins (2) through welding; the top end of the middle section grounding node (4) is connected with and provided with an independent fan (5) through a screw.

2. A fluoroplastic pipe-based flexible pipe heat sink as recited in claim 1 wherein: the upper part of the round hole on the front surface of the main radiating fin (1) is provided with an auxiliary fin (101) through welding connection; the radiating fins (1) and the auxiliary fins (101) are both of round-corner rectangular metal sheet structures; the auxiliary fins (101) are perpendicular to the main heat dissipation fins (1), and the auxiliary fins (101) are provided with grooves with three closed surfaces and one open surface.

3. A fluoroplastic pipe-based flexible pipe heat sink as recited in claim 1 wherein: the terminal radiating fin (2) is of a long rectangular metal structure with a double-layer frame, and the area of the terminal radiating fin (2) is larger than that of the main radiating fin (1); the outer ring of the terminal radiating fin (2) is an aluminum alloy frame, the inner ring of the terminal radiating fin is a copper metal embedded sheet, and the copper metal embedded sheet of the terminal radiating fin (2) is connected with the connecting rib (3) in a welding mode.

4. A fluoroplastic pipe-based flexible pipe heat sink as recited in claim 1 wherein: the connecting ribs (3) are of metal cylindrical frame structures, reinforcing circular ring nodes formed by annular metal frames are arranged at intervals on the connecting ribs (3), the outer walls of the circular ring nodes of the connecting ribs (3) are connected with the outer circular frame of the inner contact point (301) through welding, and the inner contact point (301) is fixed by the circular ring nodes; the inner contact points (301) are bilaterally symmetrical along a circular ring node; the inner contact (301) is of a metal cylindrical structure, two metal radiating discs (303), a vertical ball (302) and a metal ring frame; the metal ring frame of interior contact point (301) cup joints metal cylinder structure, and metal heat dissipation dish (303) are installed through welded connection to the top and the bottom of metal cylinder structure, and hang through the cable to install one and hang ball (302) metal heat dissipation dish (303) of bottom, and metal heat dissipation dish (303) bottom surface of bottom is the arc, and contacts with inside coiled tube.

5. A fluoroplastic pipe-based flexible pipe heat sink as recited in claim 1 wherein: a water-filled cavity serving as a cooling cavity (401) is arranged in the middle-section grounding node (4); the cooling cavity (401) is integrally sealed and is symmetrical left and right; the counterweight plate (402) is connected below the middle section grounding node (4) through welding, and the diameter of the middle section grounding node (4) is smaller than that of the counterweight plate (402); the bottom of the weight plate (402) is provided with a raised circumferential corrugated structure.

6. A fluoroplastic pipe-based flexible pipe heat sink as recited in claim 1 wherein: the independent fan (5) is a cylindrical fan structure which is powered by four No. 5 batteries and is independent in switch.

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