CN219575332U - High-efficient radiating reactor - Google Patents

Abstract

The utility model discloses a high-efficiency heat dissipation reactor which comprises a protection shell, a cover body fixing mechanism, a heat dissipation mechanism and a reactor body, wherein the protection shell is arranged with an opening at the upper end, a clamping groove is arranged at the top end of the side wall of the protection shell, a fixing chute is arranged at the upper part of the side wall of the protection shell, the fixing chute is vertical to and communicated with the clamping groove, the cover body fixing mechanism is arranged at the upper part of the side wall of the protection shell, the cover body fixing mechanism is arranged corresponding to the fixing chute, a clamping column is arranged on the lower surface of the cover body, a clamping hole is arranged on the clamping column, the clamping column is matched with the clamping groove, the cover body fixing mechanism is matched with the clamping hole, the cover body is provided with the heat dissipation groove, a supporting plate is arranged in the protection shell, the heat dissipation hole or the supporting plate is arranged as a grid plate structure, and an installation cavity is arranged above the supporting plate. The utility model relates to the technical field of reactors, and particularly provides a high-efficiency heat-dissipation reactor which has a high-efficiency heat-dissipation function and can conveniently take out a reactor body from a protective shell for maintenance.

Description

High-efficient radiating reactor

Technical Field

The utility model relates to the technical field of reactors, in particular to a high-efficiency heat dissipation reactor.

Background

The reactor is an inductor, is a common anti-interference element in an electronic circuit, is provided with a magnetic ring and a coil, and is provided with an alternating current in the coil, so that magnetic lines of force changing along with time are displayed around the coil. In order to ensure the normal operation of the reactor, it is necessary to efficiently dissipate heat of the reactor; in addition, the prior reactor has the technical defect of inconvenient taking out and overhauling from the protective shell.

Disclosure of Invention

Aiming at the situation, in order to make up the prior defects, the utility model provides the high-efficiency heat dissipation reactor which has the high-efficiency heat dissipation function and can conveniently take out the reactor body from the protective shell for maintenance.

The utility model provides the following technical scheme: the utility model provides a high-efficiency radiating reactor, which comprises a protective shell, a cover body fixing mechanism, a radiating mechanism and a reactor body, wherein the protective shell is arranged with an opening at the upper end, a clamping groove is arranged at the top end of the side wall of the protective shell, a fixing chute is arranged at the upper part of the side wall of the protective shell, the fixing chute is vertical and communicated with the clamping groove, the cover body fixing mechanism is arranged at the upper part of the side wall of the protective shell, the cover body fixing mechanism is arranged corresponding to the fixing chute, the lower surface of the cover body is provided with a clamping column, the clamping column is provided with a clamping hole, the clamping column is matched with the clamping groove, the cover body fixing mechanism is matched with the clamping hole, the cover body is provided with a radiating groove, a supporting plate is arranged in the protective shell, the supporting plate is provided with a grid plate structure, a mounting cavity is arranged above the supporting plate, a radiating cavity is arranged below the supporting plate, the reactor body is arranged above the supporting plate, the radiating mechanism is arranged in the radiating cavity, and the upper side wall of the radiating mechanism is provided with an air inlet groove and the radiating groove is arranged in the radiating cavity.

For realizing the connection of lid and protective housing, lid fixed establishment includes protective housing, fixed subassembly, pushes down the subassembly and inserts the subassembly, the protective housing is equipped with on the lateral wall of protective housing, fixed subassembly is located on the roof of protective housing, push down the subassembly and slide and locate on the roof of protective housing, push down the upper portion of subassembly and correspond the setting with fixed subassembly, it locates on the lateral wall of protective housing to inlay to insert the subassembly slip, it corresponds the setting with the lower part of pushing down the subassembly to inlay and insert the subassembly, inlay the card of inserting subassembly and block post and inlay the hole adaptation.

Further, the pushing component comprises a pushing sliding column, a first reset spring and a pushing protruding piece, the pushing sliding column is slidably arranged on the top wall of the protective box, the pushing protruding piece is arranged at the lower end of the pushing sliding column, a fixing hole is formed in the upper portion of the pushing sliding column, the first reset spring is arranged on the pushing sliding column in a sleeved mode, two ends of the first reset spring are connected with the top wall of the protective box and the pushing protruding piece respectively, and the lower surface of the pushing protruding piece is an arc-shaped surface.

Further, insert the subassembly and insert the sliding column, reset spring second and insert the impeller including inlaying, it locates on the lateral wall of protective housing to inlay to insert the sliding column slip, it locates the one end of inlaying to insert the sliding column to insert the impeller, it inserts the hole adaptation to inlay the free end of inserting the sliding column with the card, it inserts the upper surface of impeller and keep away from the side of inlaying the sliding column and be the arcwall face, it is located the lower extreme of pushing down protruding piece to insert the impeller, reset spring second cover is located and is inserted on the sliding column, reset spring second's both ends link to each other with the lateral wall of protective housing and the impeller of inlaying respectively.

Further, fixed subassembly includes mounting panel, fixed slide post, limiting plate, arm-tie and fixed spring, the mounting panel is located on the roof of protective housing, fixed slide post slides and locates on the mounting panel, the middle part of fixed slide post is located to the limiting plate, the one end of fixed slide post is located to the arm-tie, arm-tie and limiting plate are located the both sides of mounting panel, fixed spring cover is located on the fixed slide post, fixed spring's both ends link to each other with mounting panel and limiting plate respectively, the free end of fixed slide post and the fixed hole adaptation of pushing down the slide post.

For improving the radiating efficiency of electric reactor body, radiating mechanism includes protective housing, heat dissipation motor, initiative cone pulley and radiator unit, the protective housing is located on the interior diapire of protective housing, the heat dissipation motor is located on the interior diapire of protective housing and is located the protective housing, on the output shaft of heat dissipation motor was located to the initiative cone pulley, radiator unit is equipped with two sets of about the driving gear symmetry, radiator unit corresponds the setting with the air inlet groove.

Further, the heat dissipation assembly comprises a driven conical wheel, a heat dissipation driving shaft and heat dissipation fan blades, the heat dissipation driving shaft is rotationally arranged on the side wall of the protective shell, the driven conical wheel is arranged at one end of the heat dissipation driving shaft, which is located in the protective shell, the driven conical wheel is meshed with the driving conical wheel, the heat dissipation fan blades are arranged at one end of the heat dissipation driving shaft, which is far away from the driven conical wheel, and the heat dissipation fan blades are correspondingly arranged with the air inlet groove.

Preferably, the side walls of the reactor body are uniformly provided with radiating fins.

The beneficial effects obtained by the utility model by adopting the structure are as follows: according to the reactor with high-efficiency heat dissipation, the protective shell and the cover body can be conveniently installed and detached through the cover body fixing mechanism, so that the reactor body can be conveniently detached and overhauled; meanwhile, the rapid exchange of air flow in the protective shell can be realized through the arrangement of the heat dissipation mechanism, so that the heat dissipation requirement of the reactor body is met.

Drawings

The accompanying drawings are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate the utility model and together with the embodiments of the utility model, serve to explain the utility model. In the drawings:

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

fig. 2 is a schematic structural view of the cover fixing mechanism of the present utility model.

Wherein, 1, a protective shell, 2, a cover body, 3, a cover body fixing mechanism, 4, a heat dissipation mechanism, 5, a reactor body, 6, a clamping column, 7, a mounting cavity, 8, a heat dissipation cavity, 9, an air inlet groove, 10, a protective box, 11, a pushing sliding column, 12, a first reset spring, 13, a pushing convex piece, 14, a plug sliding column, 15 and a second reset spring, 16, an embedded pushing piece, 17, a mounting plate, 18, a fixed sliding column, 19, a limiting plate, 20, a pulling plate, 21, a fixed spring, 22, a protective shell, 23, a heat dissipation motor, 24, a driving cone pulley, 25, a driven cone pulley, 26, a heat dissipation driving shaft, 27, heat dissipation fan blades, 28, heat dissipation fins, 29, a supporting plate, 30 and a heat dissipation groove.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model; 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.

It should be noted that the words "front", "rear", "left", "right", "upper" and "lower" used in the following description refer to directions in the drawings, and the words "inner" and "outer" refer to directions toward or away from, respectively, the geometric center of a particular component.

As shown in fig. 1, this embodiment provides a high-efficient radiating reactor, including protective housing 1, lid 2, lid fixed establishment of institution 3, cooling mechanism 4 and reactor body 5, protective housing 1 is the upper end opening setting, protective housing 1's lateral wall top is equipped with the block groove, fixed spout has been seted up on protective housing 1's lateral wall upper portion, fixed spout is perpendicular and the intercommunication with the block groove, lid fixed establishment of institution 3 is located protective housing 1's lateral wall upper portion, lid fixed establishment of institution 3 corresponds the setting with fixed spout, lid 2's lower surface is equipped with block post 6, be equipped with the inlay hole on the block post 6, block post 6 and the adaptation of block groove, lid fixed establishment of institution 3 and the adaptation of inlay hole, set up cooling groove 30 on the lid 2, be equipped with backup pad 29 in the protective housing 1, be equipped with louvre or backup pad 29 for grid plate structure setting, backup pad 29's top is equipped with installation cavity 7, backup pad 29's below is equipped with cavity 8, reactor body 5 is placed in backup pad 29 top, reactor body 5 is equipped with cooling mechanism under lid 2 and protective housing 1 and fixed spout corresponding setting up, cooling mechanism 4 under the effect, cooling mechanism is equipped with cooling groove 9 under cooling groove, cooling mechanism is equipped with cooling groove 9, cooling mechanism is with cooling groove 3, cooling mechanism is with cooling groove under the effect of cooling mechanism, cooling mechanism is equipped with cooling groove 9, cooling mechanism is with cooling groove 9, cooling groove is all in the air inlet 5.

Specifically: referring to fig. 1 and 2, in this embodiment, the cover fixing mechanism 3 includes a protective case 10, a fixing component, a pressing component and an inserting component, the protective case 10 is provided on a side wall of the protective case 1, the fixing component is provided on a top wall of the protective case 10, the pressing component is slidably provided on the top wall of the protective case 10, an upper portion of the pressing component is correspondingly provided with the fixing component, the inserting component is slidably provided on a side wall of the protective case 10, the inserting component is correspondingly provided with a lower portion of the pressing component, the inserting component is adapted with a clamping hole of the clamping column 6, the pressing component includes a pressing slide column 11, a first return spring 12 and a pressing protrusion 13, the pressing slide column 11 is slidably provided on the top wall of the protective case 10, the pressing protrusion 13 is provided on a lower end of the pressing slide column 11, a fixing hole is provided above the pressing slide column 11, the first return spring 12 is sleeved on the pressing slide column 11, the two ends of the first return spring 12 are respectively connected with the top wall of the protective box 10 and the pressing-down convex piece 13, the lower surface of the pressing-down convex piece 13 is an arc surface, the embedding assembly comprises an embedding slide column 14, a second return spring 15 and an embedding pushing piece 16, the embedding slide column 14 is arranged on the side wall of the protective box 10 in a sliding manner, the embedding pushing piece 16 is arranged at one end of the embedding slide column 14, the free end of the embedding slide column 14 is matched with the embedding hole, the upper surface of the embedding pushing piece 16 and the side surface far away from the embedding slide column 14 are arc surfaces, the embedding pushing piece 16 is arranged at the lower end of the pressing-down convex piece 13, the second return spring 15 is sleeved on the embedding slide column 14, the two ends of the second return spring 15 are respectively connected with the side wall of the protective box 10 and the embedding pushing piece 16, when the pressing-down slide column 11 is pressed down, the embedding slide column 14 can be pushed into the embedding hole through the pressing-down convex piece 13, the connection of the cover body 2 and the protective shell 1 can be realized, the fixed subassembly includes mounting panel 17, fixed slide post 18, limiting plate 19, arm-tie 20 and fixed spring 21, mounting panel 17 is located on the roof of protective housing 10, fixed slide post 18 slides and locates on mounting panel 17, the middle part of fixed slide post 18 is located to limiting plate 19, the one end of fixed slide post 18 is located to arm-tie 20, arm-tie 20 and limiting plate 19 are located the both sides of mounting panel 17, fixed spring 21 cover is located on fixed slide post 18, the both ends of fixed spring 21 link to each other with mounting panel 17 and limiting plate 19 respectively, the free end of fixed slide post 18 and the fixed hole adaptation of pushing down slide post 11, under the effect of fixed spring 21, the free end of fixed slide post 18 can be stablely embedded in the fixed hole of pushing down slide post 11, thereby guarantee to push down the subassembly and push down the embedding subassembly all the time.

Specifically: referring to fig. 1, in this embodiment, the heat dissipation mechanism 4 includes a protection shell 22, a heat dissipation motor 23, a driving cone 24 and a heat dissipation assembly, the protection shell 22 is disposed on an inner bottom wall of the protection shell 1, the heat dissipation motor 23 is disposed on the inner bottom wall of the protection shell 1 and is located in the protection shell 22, the driving cone 24 is disposed on an output shaft of the heat dissipation motor 23, the heat dissipation assembly is symmetrically disposed about the driving gear and is provided with two groups, the heat dissipation assembly is disposed corresponding to the air inlet slot 9, the heat dissipation assembly includes a driven cone 25, a heat dissipation driving shaft 26 and heat dissipation fan blades 27, the heat dissipation driving shaft 26 is rotationally disposed on a side wall of the protection shell 22, the driven cone 25 is disposed at one end of the heat dissipation driving shaft 26 located in the protection shell 22, the driven cone 25 is engaged with the driving cone 24, the heat dissipation fan blades 27 are disposed at one end of the heat dissipation driving shaft 26 away from the driven cone 25, and the heat dissipation fan blades 27 are disposed corresponding to the air inlet slot 9.

Specifically: referring to fig. 1, in the present embodiment, heat dissipation fins 28 are uniformly distributed on the side wall of the reactor body 5.

When the reactor is particularly used, the driving conical wheel 24 can be driven to rotate under the action of the heat dissipation motor 23, the driving conical wheel 24 is meshed with the driven conical wheel 25 to drive the heat dissipation driving shaft 26 to rotate, and the heat dissipation driving shaft 26 drives the heat dissipation fan blades 27 to rotate, so that external low-temperature air is sucked into the protective shell 1, and the low-temperature air rises into the installation cavity 7 along the clearance of the heat dissipation hole or the grid plate supporting plate 29 to efficiently dissipate heat of the reactor body 5; when the reactor body 5 needs to be overhauled, only the pulling plate 20 is needed, the pulling plate 20 drives the fixed slide column 18 to move out of the fixed hole, the embedded slide column 14 slides out of the embedded hole under the action of the first reset spring 12 and the second reset spring 15, and the cover body 2 can be conveniently removed, and the reactor body 5 is taken out.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

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

Claims (8)

1. A high-efficient radiating reactor, its characterized in that: including protective housing, lid fixed establishment, cooling mechanism and reactor body, protective housing is the upper end opening setting, protective housing's lateral wall top is equipped with the joint groove, fixed spout has been seted up on protective housing's lateral wall upper portion, fixed spout is perpendicular and the intercommunication with the joint groove, lid fixed establishment locates protective housing's lateral wall upper portion, lid fixed establishment corresponds the setting with fixed spout, the lower surface of lid is equipped with the block post, be equipped with the inlay card hole on the block post, block post and the adaptation of joint groove, be equipped with the backup pad in the protective housing with inlay card hole adaptation, the heat dissipation groove has been seted up on the lid, be equipped with the louvre in the backup pad or the backup pad is grid plate structure setting, the top of backup pad is equipped with the installation cavity, the below of backup pad is equipped with the chamber, reactor body is placed in the backup pad top, cooling mechanism locates the heat dissipation intracavity, the air inlet groove has been seted up on the lateral wall of chamber, air inlet groove and heat dissipation groove all are equipped with the filter screen.

2. The high-efficiency heat dissipation reactor according to claim 1, wherein: the cover body fixing mechanism comprises a protective box, a fixing component, a pressing component and an embedding component, wherein the protective box is arranged on the side wall of a protective shell, the fixing component is arranged on the top wall of the protective box, the pressing component is arranged on the top wall of the protective box in a sliding mode, the upper portion of the pressing component is arranged corresponding to the fixing component, the embedding component is arranged on the side wall of the protective box in a sliding mode, the embedding component is arranged corresponding to the lower portion of the pressing component, and the embedding component is matched with the clamping hole of the clamping column.

3. The high-efficiency heat dissipation reactor according to claim 2, wherein: the upper part of the lower sliding column is provided with a fixing hole, the lower sliding column is sleeved with the reset spring, two ends of the reset spring are respectively connected with the top wall of the protective box and the lower protruding part, and the lower surface of the lower protruding part is an arc-shaped surface.

4. A high efficiency heat dissipating reactor according to claim 3, wherein: the embedded component comprises an embedded sliding column, a second reset spring and an embedded pushing piece, wherein the embedded sliding column is arranged on the side wall of the protective box in a sliding mode, the embedded pushing piece is arranged at one end of the embedded sliding column, the free end of the embedded sliding column is matched with the clamping hole, the upper surface of the embedded pushing piece and the side face, far away from the embedded sliding column, of the embedded pushing piece are arc-shaped, the embedded pushing piece is located at the lower end of the pressing protruding piece, the second reset spring is arranged on the embedded sliding column in a sleeved mode, and two ends of the second reset spring are connected with the side wall of the protective box and the embedded pushing piece respectively.

5. The high-efficiency heat dissipation reactor according to claim 4, wherein: the fixed subassembly includes mounting panel, fixed slide post, limiting plate, arm-tie and fixed spring, the mounting panel is located on the roof of protective housing, fixed slide post slides and locates on the mounting panel, the middle part of fixed slide post is located to the limiting plate, the one end of fixed slide post is located to the arm-tie, arm-tie and limiting plate are located the both sides of mounting panel, fixed spring cover is located on the fixed slide post, the both ends of fixed spring link to each other with mounting panel and limiting plate respectively, the free end of fixed slide post and the fixed hole adaptation of pushing down the slide post.

6. The high-efficiency heat dissipation reactor according to claim 1, wherein: the heat dissipation mechanism comprises a protective shell, a heat dissipation motor, a driving conical wheel and heat dissipation components, wherein the protective shell is arranged on the inner bottom wall of the protective shell, the heat dissipation motor is arranged on the inner bottom wall of the protective shell and is positioned in the protective shell, the driving conical wheel is arranged on an output shaft of the heat dissipation motor, the heat dissipation components are symmetrically arranged in two groups relative to the driving gear, and the heat dissipation components are correspondingly arranged with the air inlet groove.

7. The high-efficiency heat dissipation reactor of claim 6, wherein: the heat dissipation assembly comprises a driven conical wheel, a heat dissipation driving shaft and heat dissipation fan blades, the heat dissipation driving shaft is rotationally arranged on the side wall of the protective shell, the driven conical wheel is arranged at one end of the heat dissipation driving shaft, which is located in the protective shell, the driven conical wheel is meshed with the driving conical wheel, the heat dissipation fan blades are arranged at one end of the heat dissipation driving shaft, which is far away from the driven conical wheel, and the heat dissipation fan blades are correspondingly arranged with the air inlet groove.

8. The high-efficiency heat dissipation reactor according to claim 1, wherein: radiating fins are uniformly distributed on the side wall of the reactor body.