CN217083385U - Energy-saving radiator - Google Patents

Abstract

The utility model discloses an energy-saving radiator relates to radiator technical field. The utility model comprises a frame component, a heat radiation component, a side plate component and a limit component; a plurality of heat dissipation assemblies are arranged at the bottom in the frame assembly in a sliding manner; a side plate assembly is arranged inside the frame assembly in a sliding manner; and two ends inside the frame component are in sliding fit with the limiting components. The utility model utilizes the heat generated by the electronic element to flow into the heat dissipation cylinder and the heat dissipation fins through the first flange communication cylinder and the second flange communication cylinder and finally flow out of the heat dissipation device through the heat dissipation groove, thereby realizing indoor heating, improving the utilization rate of heat resources and playing a certain energy-saving role; through the design to spacing subassembly for its extrusion force to side plate subassembly and radiator unit diminishes, finally reaches the effect of loose relatively between a plurality of radiator unit, makes things convenient for the later stage to change the radiator unit who damages, has simplified the operating procedure, has brought certain convenience for the staff.

Description

Energy-saving radiator

Technical Field

The utility model belongs to the technical field of the radiator, especially, relate to an energy-saving radiator.

Background

Radiators are important and essential components of hot water (or steam) heating systems. The hot water is cooled in the radiator (or steam is condensed in the radiator) to supply heat to the indoor, thereby achieving the purpose of heating. The metal consumption and the manufacturing cost of the radiator occupy a considerable proportion in the heating system, so that the correct selection of the radiator relates to the economic index and the operation effect of the system.

However, the existing radiator can quickly radiate liquid needing to radiate heat, and heat generated in the operation process is used for indoor heating, so that certain heat resource utilization rate can be improved, and a certain energy-saving effect is achieved at the same time, but the radiating plates of the existing plate radiator are strung together through one or more guide rods, then a plurality of radiating plates are fixed together through extrusion of the extrusion plate, when one of the radiating plates is damaged, all the plates before the damaged plate need to be disassembled to be replaced, the operation is complex, and certain inconvenience is brought to replacement personnel.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing an energy-saving radiator, through to frame subassembly, radiator unit, curb plate subassembly and spacing subassembly, it can dispel the heat fast with needs radiating liquid to have solved current radiator, and be used for indoor heating with its produced heat of operation in-process, thereby can improve certain heat resource utilization ratio, certain energy-conserving effect has also been played simultaneously, and the heating panel complex operation that certain damage was changed to current radiator, the problem of certain inconvenience has been brought for the renewal personnel.

In order to solve the technical problem, the utility model discloses a realize through following technical scheme:

the utility model relates to an energy-saving radiator, which comprises a frame component, a radiating component, a side plate component and a limiting component; a plurality of heat dissipation assemblies are arranged at the bottom in the frame assembly in a sliding manner; a side plate assembly is arranged inside the frame assembly in a sliding manner; the two ends in the frame assembly are in sliding fit with limiting assemblies; the limiting assembly is in sliding fit with the heat dissipation assembly; the limiting assembly is in sliding fit with the side plate assembly;

the limiting assembly comprises a U-shaped frame; i-shaped rails are fixed at two ends of the U-shaped frame; a T-shaped frame is fixed at the top of one I-shaped rail; one end of the T-shaped frame is rotatably connected with a perforated plate through a torsion spring; a fastening disc threaded part is rotationally matched with the threads on one side of the perforated plate; the fastening disc screw is in rotating fit with the screw thread of the perforated plate.

Further, the frame assembly comprises a U-shaped frame; limiting grooves are formed in two ends of the interior of the U-shaped frame; the inner walls of the limiting grooves are all fixed with limiting rails; the limiting groove is in sliding fit with the I-shaped rail and is clamped with the I-shaped rail;

and a plurality of mounting holes are formed in the bottom of the U-shaped frame.

Furthermore, two symmetrical sliding grooves are formed in two ends of the interior of the U-shaped frame;

a first threaded hole is formed in one side of the outer wall of the U-shaped frame; the first threaded hole is in threaded rotation fit with the fastening disc threaded piece;

and two groups of first flange communicating cylinders are communicated with one side of the outer wall of the U-shaped frame.

Further, the heat dissipation assembly comprises a heat dissipation frame; radiating fins are fixed inside the radiating frame; the surfaces of the radiating fins are communicated with two groups of radiating cylinders; the heat dissipation cylinder and the first flange communication cylinder are mutually attached;

the two opposite side surfaces of the heat dissipation frame are symmetrically provided with heat dissipation grooves; two ends of the heat dissipation frame are provided with first rectangular grooves; the first rectangular groove is in sliding fit with the U-shaped frame and is clamped with the U-shaped frame;

and a pull rod is fixed on one side of the heat dissipation frame.

Further, the side plate assembly comprises a side plate; two ends of each side pressing plate are provided with second rectangular grooves; the second rectangular groove is in sliding fit with the U-shaped frame and is clamped with the U-shaped frame;

the two ends of each side pressing plate are fixed with a movable clamping rail; the movable clamping rail is in sliding fit with the sliding groove and is clamped with the sliding groove;

one side of the side pressing plate is communicated with two groups of second flange communicating cylinders; the second flange communication cylinder is attached to the heat dissipation cylinder.

Furthermore, two opposite side surfaces of the U-shaped frame are symmetrically provided with pressing plate sliding grooves; the pressing plate sliding groove is matched with the extrusion plate in a sliding mode, and the pressing plate sliding groove and the extrusion plate are clamped;

and the outer side wall of the U-shaped frame is in threaded running fit with a disc threaded part.

The utility model discloses following beneficial effect has:

1. the utility model discloses utilize the heat that electronic component produced, through a first flange intercommunication section of thick bamboo and a second flange intercommunication section of thick bamboo, flow in a heat dissipation section of thick bamboo and radiating fin to finally through the radiating groove that the side pressure board both ends were seted up, the radiator that flows out is outside, has realized indoor heating, has improved hot resource utilization, has also played certain energy-conserving effect simultaneously.

2. The utility model discloses a rotate fastening disc screw for fastening disc screw separates with first screw hole, then stirs the orifice plate, makes it be in horizontal position, stimulates the U-shaped frame, rotates disc screw simultaneously, makes the stripper plate diminish to the extrusion force of side plate subassembly, finally makes between a plurality of radiator unit of frame subassembly loose relatively, makes things convenient for the later stage to change the radiator unit of damage, has simplified operating procedure, has brought certain convenience for the staff.

Of course, it is not necessary for any particular product to achieve all of the above-described advantages at the same time.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic structural diagram of an energy-saving radiator.

Fig. 2 is a schematic structural view of the frame assembly.

Fig. 3 is a schematic structural diagram of the heat dissipation assembly.

Fig. 4 is a schematic structural view of the side plate assembly.

Fig. 5 is a schematic structural view of the limiting assembly.

In the drawings, the components represented by the respective reference numerals are listed below:

1-frame component, 101-U-shaped frame, 102-limiting groove, 103-limiting rail, 104-mounting hole, 105-sliding groove, 106-first threaded hole, 107-first flange communicating cylinder, 2-radiating component, 201-radiating frame, 202-radiating fin, 203-radiating cylinder, 204-radiating groove, 205-first rectangular groove, 3-side plate component, 301-side pressure plate, 302-second rectangular groove, 303-moving clamping rail, 304-second flange communicating cylinder, 4-limiting component, 401-U-shaped frame, 402-I-shaped rail, 403-T-shaped frame, 404-perforated plate, 405-fastening disk threaded component, 406-pressing plate sliding groove, 407-extruding plate, and 408-disk threaded component.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by a person of ordinary skill in the art without creative efforts belong to the protection scope of the present invention.

Referring to fig. 1-5, the present invention relates to an energy-saving heat sink, which comprises a frame assembly 1, a heat dissipation assembly 2, a side plate assembly 3 and a limiting assembly 4; a plurality of heat dissipation assemblies 2 are arranged at the bottom in the frame assembly 1 in a sliding manner; a side plate component 3 is arranged inside the frame component 1 in a sliding way; the two ends in the frame component 1 are matched with the limiting components 4 in a sliding way; the limiting component 4 is in sliding fit with the heat dissipation component 2; the limiting component 4 is in sliding fit with the side plate component 3;

the limiting component 4 comprises a U-shaped frame 401; i-shaped rails 402 are fixed at two ends of the U-shaped frame 401; a T-shaped frame 403 is fixed on the top of one I-shaped rail 402; one end of the T-shaped frame 403 is rotatably connected with a perforated plate 404 through a torsion spring; a fastening disc threaded part 405 is in threaded rotation fit with one side of the perforated plate 404; the fastening disc screw 405 is in threaded rotational engagement with the perforated plate 404; the radiating pipe of the electronic element is communicated with the first flange communicating cylinder 107 and the second flange communicating cylinder 304, because the radiating cylinder 203 and the first flange communicating cylinder 107 are mutually attached, and the second flange communicating cylinder 304 and the radiating cylinder 203 are mutually attached, when the heat generated by the electronic element flows into the radiating cylinder 203 and the radiating fins 202 through the first flange communicating cylinder 107 and the second flange communicating cylinder 304, and finally flows out of the radiator through the radiating grooves 204 formed at the two ends of the side pressure plate 301, so that indoor heating is realized, the utilization rate of heat resources is improved, and meanwhile, a certain energy-saving effect is also achieved.

Wherein, the frame component 1 comprises a U-shaped frame 101; limiting grooves 102 are formed in two ends of the interior of the U-shaped frame 101; the inner walls of the limiting grooves 102 are fixed with limiting rails 103; the limiting groove 102 is in sliding fit with the I-shaped rail 402 and is clamped with the I-shaped rail;

the bottom of the U-shaped frame 101 is provided with a plurality of mounting holes 104; a plurality of mounting holes 104 formed in the bottom of the U-shaped frame 101 are fixed to the electronic component to be cooled by bolts.

Wherein, two symmetrical sliding grooves 105 are respectively arranged at two ends inside the U-shaped frame 101;

a first threaded hole 106 is formed in one side of the outer wall of the U-shaped frame 101; the first threaded hole 106 is in threaded rotational engagement with the fastening disc screw 405;

two groups of first flange communicating cylinders 107 are communicated with one side of the outer wall of the U-shaped frame 101; through first screw hole 106 and fastening disc screw 405 screw thread normal running fit for spacing subassembly 4 carries out spacing fixed to a plurality of radiator unit 2 and curb plate subassembly 3 inside frame subassembly 1, prevents that whole radiator from taking place loosely.

The heat dissipation assembly 2 includes a heat dissipation frame 201; a heat dissipation fin 202 is fixed inside the heat dissipation frame 201; the surfaces of the radiating fins 202 are communicated with two groups of radiating cylinders 203; the heat dissipation cylinder 203 and the first flange communication cylinder 107 are mutually attached;

the opposite two side surfaces of the heat dissipation frame 201 are symmetrically provided with heat dissipation grooves 204; two ends of the heat dissipation frame 201 are provided with first rectangular grooves 205; the first rectangular groove 205 is in sliding fit with the U-shaped frame 401 and is clamped with the U-shaped frame;

a pull rod is fixed on one side of the heat dissipation frame 201; through rotating fastening disc screw 405, make fastening disc screw 405 separate with first screw hole 106, then stir perforated plate 404, make it be in horizontal position, rotate disc screw 408 simultaneously, make the extrusion force of stripper plate 407 to side plate subassembly 3 diminish, finally make relatively loose between a plurality of radiator unit 2 of frame subassembly 1 inside, pulling U-shaped frame 401, make first rectangular channel 205 and the U-shaped frame 401 sliding separation of seting up at radiator frame 201 both ends, the pull rod of pulling radiator frame 201 one side fixed, make radiator unit 2 that damages take out from the inside of frame subassembly 1, and change, made things convenient for the later stage to change radiator unit 2 that damages.

Wherein, the side plate component 3 comprises a side pressing plate 301; two ends of each side pressing plate 301 are provided with second rectangular grooves 302; the second rectangular groove 302 is in sliding fit with the U-shaped frame 401 and is clamped with the U-shaped frame;

two ends of the side pressing plate 301 are both fixed with movable clamping rails 303; the movable clamping rail 303 is in sliding fit with the sliding groove 105 and is clamped with the sliding groove;

one side of the side pressing plate 301 is communicated with two groups of second flange communicating cylinders 304; the second flange connecting cylinder 304 is mutually attached to the heat dissipation cylinder 203; through rotating fastening disc screw 405 for fastening disc screw 405 separates with first screw hole 106, then stirs foraminiferous plate 404, makes it be in horizontal position, pulling U-shaped frame 401, rotates disc screw 408 simultaneously, makes extrusion plate 407 diminish to the extrusion force of side plate subassembly 3, finally makes between a plurality of radiator unit 2 of frame subassembly 1 inside loose relatively, makes things convenient for the later stage to change the radiator unit 2 of damage.

Wherein, two opposite side surfaces of the U-shaped frame 401 are symmetrically provided with pressing plate sliding grooves 406; the pressing plate sliding chute 406 is in sliding fit with the extrusion plate 407, and the two are clamped;

the outer side wall of the U-shaped frame 401 is in threaded rotation fit with a disc threaded part 408; through rotating disc screw 408, because of clamp plate spout 406 and stripper plate 407 slip joint, so when rotating disc screw 408, can finally extrude the operation through extrusion stripper plate 407 to side board subassembly 3, realized extruding fixedly a plurality of radiator unit 2 to the inside sliding fit of frame subassembly 1.

The working principle of the embodiment is as follows:

the mounting hole 104 and the electronic element to be radiated are mounted and fixed through the bolt, the radiating pipe of the electronic element is communicated with the first flange communicating cylinder 107 and the second flange communicating cylinder 304, and because the radiating cylinder 203 and the first flange communicating cylinder 107 are mutually attached, and the second flange communicating cylinder 304 and the radiating cylinder 203 are mutually attached, when heat generated by the electronic element flows into the radiating cylinder 203 and the radiating fins 202 through the first flange communicating cylinder 107 and the second flange communicating cylinder 304 and finally flows out of the radiator through the radiating groove 204, indoor heating is realized, the utilization rate of heat resources is improved, and a certain energy-saving effect is achieved; when the heat dissipation assembly 3 is damaged, the fastening disc screw 405 is rotated to separate the fastening disc screw 405 from the perforated plate 404, then the perforated plate 404 is shifted to be in a horizontal position, meanwhile, the disc screw 408 is rotated to reduce the extrusion force of the extrusion plate 407 on the side plate assembly 3, finally, a plurality of heat dissipation assemblies 2 in the frame assembly 1 are relatively loosened, the U-shaped frame 401 is pulled to slidably separate the first rectangular groove 205 arranged at the two ends of the heat dissipation frame 201 from the U-shaped frame 401, the pull rod fixed on one side of the heat dissipation frame 201 is pulled to draw out the damaged heat dissipation assembly 2 from the inside of the frame assembly 1 and replace the damaged heat dissipation assembly 2, after the replacement is finished, the limiting assembly 4 is pushed to be clamped in a sliding fit manner between the first rectangular groove 205 and the U-shaped frame 401 and to be clamped in a sliding fit manner between the second rectangular groove 302 and the U-shaped frame 401, and finally the fastening disc screw 405 is rotated again, make fastening disc screw member 405 and first screw hole 106 be connected fixedly, rotate disc screw member 408 simultaneously for stripper plate 407 carries out the extrusion operation to side plate subassembly 3, has made things convenient for the later stage to change damaged radiator unit 2, has simplified the operating procedure, has brought certain convenience for the staff.

In the description herein, references to the description of "one embodiment," "an example," "a specific example," etc., 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 invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. 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 present invention disclosed above are intended only to help illustrate the present invention. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise embodiments 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 invention and its practical applications, to thereby enable others skilled in the art to best understand the invention for and utilize the invention. The present invention is limited only by the claims and their full scope and equivalents.

Claims (6)

1. An energy-saving radiator comprises a frame assembly (1), a radiating assembly (2), a side plate assembly (3) and a limiting assembly (4); the method is characterized in that: a plurality of heat dissipation assemblies (2) are arranged at the bottom in the frame assembly (1) in a sliding manner; a side plate assembly (3) is arranged inside the frame assembly (1) in a sliding manner; two ends of the interior of the frame component (1) are in sliding fit with limiting components (4); the limiting component (4) is in sliding fit with the heat dissipation component (2); the limiting assembly (4) is in sliding fit with the side plate assembly (3);

the limiting component (4) comprises a U-shaped frame (401); an I-shaped rail (402) is fixed at both ends of the U-shaped frame (401); a T-shaped frame (403) is fixed at the top of one H-shaped rail (402); one end of the T-shaped frame (403) is rotatably connected with a perforated plate (404) through a torsion spring; a fastening disc threaded part (405) is in threaded rotary fit with one side of the perforated plate (404); the fastening disc screw (405) is in threaded rotational fit with the perforated plate (404).

2. An energy efficient heat sink according to claim 1, characterized in that the frame assembly (1) comprises a U-shaped frame (101); limiting grooves (102) are formed in two ends of the interior of the U-shaped frame (101); the inner walls of the limiting grooves (102) are all fixed with limiting rails (103); the limiting groove (102) is in sliding fit with the I-shaped rail (402) and is clamped with the I-shaped rail;

the bottom of the U-shaped frame (101) is provided with a plurality of mounting holes (104).

3. The energy-saving radiator according to claim 2, wherein two symmetrical sliding grooves (105) are formed at two ends of the inside of the U-shaped frame (101);

a first threaded hole (106) is formed in one side of the outer wall of the U-shaped frame (101); the first threaded hole (106) is in threaded rotation fit with a fastening disc threaded piece (405);

and one side of the outer wall of the U-shaped frame (101) is communicated with two groups of first flange communicating cylinders (107).

4. An energy-saving radiator according to claim 3, characterized in that the heat-radiating assembly (2) comprises a heat-radiating frame (201); a radiating fin (202) is fixed inside the radiating frame (201); the surfaces of the radiating fins (202) are communicated with two groups of radiating cylinders (203); the heat dissipation cylinder (203) is attached to the first flange communication cylinder (107);

the two opposite side surfaces of the heat dissipation frame (201) are symmetrically provided with heat dissipation grooves (204); two ends of the heat dissipation frame (201) are provided with first rectangular grooves (205); the first rectangular groove (205) is in sliding fit with the U-shaped frame (401) and is clamped with the U-shaped frame;

and a pull rod is fixed on one side of the heat dissipation frame (201).

5. An energy saving radiator according to claim 4, wherein said side plate assembly (3) comprises side plates (301); two ends of each side pressing plate (301) are provided with second rectangular grooves (302); the second rectangular groove (302) is in sliding fit with the U-shaped frame (401) and is clamped with the U-shaped frame;

two ends of each side pressing plate (301) are fixed with a movable clamping rail (303); the movable clamping rail (303) is in sliding fit with the sliding groove (105) and is clamped with the sliding groove;

one side of the side pressure plate (301) is communicated with two groups of second flange communicating cylinders (304); the second flange connecting cylinder (304) is attached to the heat radiating cylinder (203).

6. The energy-saving radiator according to claim 5, wherein the U-shaped frame (401) is symmetrically provided with pressing plate sliding grooves (406) on two opposite side surfaces; the pressing plate sliding groove (406) is in sliding fit with the extrusion plate (407), and the two are clamped;

and a disc threaded piece (408) is in threaded rotating fit with the outer side wall of the U-shaped frame (401).

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