Intensive bus duct with heat dissipation effect
Technical Field
The utility model belongs to the bus duct field specifically is an intensive bus duct with radiating effect.
Background
According to the authorized bulletin number: CN216489646U, entitled "dense busway with heat dissipation effect", which is described in the specification: the intensive bus duct with the heat dissipation effect has the advantages that through the arranged dust removal net, when the motor is started to work, the motor drives the heat dissipation fan to work, so that the air flow rate of a bus duct shell is increased by the rotation of the plurality of fan blades of the heat dissipation fan, through the arranged plurality of dust removal holes, the air circulation inside the bus duct shell is accelerated to dissipate heat, and the heat dissipation effect of the device is improved; the following drawbacks still exist:
because the bus duct length is longer, and the fan rigidity to make heat dissipation position unable change, cause the radiating effect not good.
SUMMERY OF THE UTILITY MODEL
To the above situation, for overcoming prior art's defect, the utility model provides an intensive bus duct with radiating effect, the effectual present fan rigidity of having solved to radiating position is fixed, influences the problem of radiating effect.
In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides an intensive bus duct with radiating effect, includes the bus duct body, the cell body has been seted up to the inside equidistance of bus duct body, and the internally mounted of cell body has the generating line body, and the roof is installed on the top of bus duct body, and radiator unit is installed on the top of roof, and the removal subassembly is installed on the top of roof.
Preferably, the radiating component comprises radiating grooves which are arranged on two sides of the groove body in an equidistant and symmetrical mode, the bottom ends of the radiating grooves penetrate through the bottom end of the bus duct body, and the top ends of the radiating grooves penetrate through the top end of the top plate.
Preferably, the top end of the top plate is provided with an installation body, the interior of the installation body is communicated with the top end of the heat dissipation groove, and the top end of the installation body is uniformly provided with a communication groove.
Preferably, the inner top wall of the mounting body is provided with a forward and reverse rotating motor, one end of an output shaft of the forward and reverse rotating motor is provided with a rotating shaft, and the outer side of the rotating shaft is provided with fan blades at equal angles.
Preferably, the moving assembly comprises a gear installed on the rotating shaft, the gear is located above the fan blades, and a rack is connected to the back of the gear in a meshed mode.
Preferably, the bottom of rack is symmetrically installed with the support column, support column and installation body fixed connection, and the support column is pegged graft in the inside of guide way, and the both sides of installation body are seted up to the guide way symmetry.
Preferably, the bottom symmetry of the installation body is installed the slider, and slider sliding connection is in the inside of spout, and the top of roof is seted up to the spout symmetry.
Compared with the prior art, the beneficial effects of the utility model are that:
(1) The utility model discloses, rotate through the motor output shaft that just reverses, and the gear meshes with the rack mutually, thereby after the pivot rotates, drive the installation body along rack lateral shifting, thereby make and constantly drive the radiating groove on the bus duct body and dispel the heat, thereby improve the heat dissipation scope, improve the radiating efficiency;
(2) This novel through positive reverse motor circular telegram back, the output shaft is according to certain frequency forward reverse rotation, drives the pivot forward reverse rotation then, can drive the installation body through gear and rack and remove on bus duct body top repeatedly, further improves the radiating efficiency.
Drawings
The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and together with the description serve to explain the invention and not to limit the invention.
In the drawings:
FIG. 1 is a schematic view of the present invention;
fig. 2 is a schematic view of the bus duct body structure of the present invention;
FIG. 3 is a schematic view of the structure of the installation body of the present invention;
fig. 4 is a schematic view of the rack structure of the present invention;
in the figure: 1. the bus duct body; 2. a tank body; 3. a bus body; 4. a top plate; 5. a heat dissipating component; 501. a heat sink; 502. an installation body; 503. a communicating groove; 504. a positive and negative rotation motor; 505. a rotating shaft; 506. a fan blade; 6. a moving assembly; 601. a chute; 602. a slider; 603. a gear; 604. a guide groove; 605. a rack; 606. and (4) a support column.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below 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 in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.
Embodiment one, given by fig. 1-4, the utility model discloses a bus duct body 1, cell body 2 has been seted up to bus duct body 1's inside equidistance, the internally mounted of cell body 2 has bus body 3, roof 4 is installed on bus duct body 1's top, radiator unit 5 is installed on roof 4's top, movable component 6 is installed on roof 4's top, radiator unit 5 includes that equidistance and symmetry set up in the radiating groove 501 of cell body 2 both sides, the bottom of radiating groove 501 runs through to bus duct body 1's bottom, the top of radiating groove 501 runs through to roof 4's top, installation body 502 is installed on roof 4's top, the inside of installation body 502 is linked together with the top of radiating groove 501, intercommunication groove 503 has evenly been seted up on the top of installation body 502, install positive reverse motor 504 on installation body 502's the interior roof, pivot 505 is installed to positive reverse motor 504's output shaft one end, flabellum 506 is installed to angles such as the outside of pivot 505.
In the second embodiment, on the basis of the first embodiment, the moving assembly 6 includes a gear 603 installed on the rotating shaft 505, the gear 603 is located above the fan blades 506, a rack 605 is engaged and connected to the back surface of the gear 603, support columns 606 are symmetrically installed at the bottom ends of the rack 605, the support columns 606 are fixedly connected to the installation body 502, the support columns 606 are inserted into the guide grooves 604, the guide grooves 604 are symmetrically opened at two sides of the installation body 502, sliders 602 are symmetrically installed at the bottom ends of the installation body 502, the sliders 602 are slidably connected to the inside of the sliding grooves 601, and the sliding grooves 601 are symmetrically opened at the top end of the top plate 4;
the output shaft of the forward and reverse rotating motor 504 rotates, and the gear 603 is meshed with the rack 605, so that after the rotating shaft 505 rotates, the mounting body 502 is driven to move transversely along the rack 605, and therefore heat dissipation can be performed in the heat dissipation groove 501 on the bus duct body 1 continuously, the heat dissipation range is improved, the heat dissipation efficiency is improved, the mounting body 502 can be driven to move repeatedly on the top end of the bus duct body 1, and the heat dissipation efficiency is further improved.
The working principle is as follows: when heat dissipation is performed, after the forward and reverse rotation motor 504 is powered on, the output shaft of the forward and reverse rotation motor 504 rotates to drive the rotating shaft 505 to rotate and rotate forward and reverse according to a certain frequency, and after the rotating shaft 505 rotates, the plurality of fan blades 506 rotate, so that air in the heat dissipation groove 501 on the outer side of the groove body 2 continuously circulates, and a heat dissipation effect is performed on the bus body 3 in the groove body 2;
when the rotating shaft 505 rotates forward, the plurality of fan blades 506 rotate to drive air in the heat dissipation groove 501 to enter the mounting body 502 and then to be discharged from the communicating groove 503, and external air enters the heat dissipation groove 501 from the bottom end of the heat dissipation groove 501, and the gear 603 is meshed with the rack 605, so that after the rotating shaft 505 rotates, the mounting body 502 moves transversely along the rack 605 under the action of the rack 605, and in the transverse moving process, the heat dissipation groove 501 on the bus duct body 1 is continuously driven to dissipate heat, so that the heat dissipation range is improved;
when the rotating shaft 505 rotates in the opposite direction, the plurality of blades 506 rotate in the opposite direction to drive the air in the heat dissipation groove 501 to be discharged from the bottom end of the heat dissipation groove 501, the external air enters the heat dissipation groove 501 from the communicating groove 503, and the mounting body 502 moves back in the opposite direction along the rack 605 under the action of the rack 605.