CN110822972A

CN110822972A - Energy-saving efficient nano mixed liquid sectional radiator

Info

Publication number: CN110822972A
Application number: CN201911093599.7A
Authority: CN
Inventors: 于珍
Original assignee: 于珍
Current assignee: SHENGLI OIL FIELD HAOWEI Co.,Ltd.
Priority date: 2019-11-11
Filing date: 2019-11-11
Publication date: 2020-02-21
Anticipated expiration: 2039-11-11
Also published as: CN110822972B

Abstract

The invention discloses an energy-saving efficient nano mixed liquid sectional radiator which comprises a chassis, a heat dissipation box combination, a steam cooling device, a conveying pump combination, a particle damping device and a control electric box, wherein the heat dissipation box combination is composed of a mixing box and a fan, the mixing box is installed on the side wall of the top of the chassis through bolts, a return pipe is arranged on the side wall of the top of the mixing box, a steam exhaust pipe and a water inlet pipe are arranged on one side of the mixing box from top to bottom, and a fan cover is arranged on one side of the mixing box. The invention is characterized in that the volume of the exchange cavity is periodically changed, so that the steam entering the one-way valve can guide the steam at the top of the mixing box into the exchange jacket, the low-temperature condensed water in the exchange cavity can be sent back into the mixing box by the one-way valve, meanwhile, the laser emitter on the piston head can emit laser, and according to the principles of Doppler effect and atomic energy level quantization of light, the laser can cool down the water molecules which move violently, thereby reducing the steam saturation and improving the heat exchange quantity.

Description

Energy-saving efficient nano mixed liquid sectional radiator

Technical Field

The invention relates to the technical field of energy-saving instruments, in particular to an energy-saving efficient nano mixed liquid sectional radiator.

Background

The radiator used by industry and equipment is a device which discharges heat generated by the operation of machinery or an engine and ensures that the machinery or the engine works under the condition of allowing the working temperature, the quality of the radiator directly influences the working efficiency of the equipment or the engine, but the radiator used at present has simple structure and single function and has a great number of problems: the traditional cooling media mainly comprise water and kerosene, wherein water is the best heat dissipation effect in the liquid medium, but the water circulation cooling cannot be satisfied in time for a large amount of heat exchange; the invention provides an energy-saving efficient nano mixed liquid segmented radiator, which is easy to generate steam after heat exchange with a lower boiling point of a water body, has poor heat exchange effect, and is easy to crack due to frequent expansion with heat and contraction with cold of equipment.

Disclosure of Invention

The invention aims to provide an energy-saving efficient nano mixed liquid sectional radiator to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme:

an energy-saving efficient nanometer mixed liquid segmented radiator comprises a chassis, a heat dissipation box combination, a steam cooling device, a delivery pump combination, a particle damping device and a control electric box, wherein the heat dissipation box combination comprises a mixing box and a fan, the mixing box is installed on the top side wall of the chassis through bolts, a return pipe is arranged on the top side wall of the mixing box, one side of the mixing box is provided with an exhaust pipe and an inlet pipe from top to bottom, one side of the mixing box is provided with a fan cover, a positioning sleeve is arranged on one end side wall of the fan cover, a positioning plate is welded on the inner side wall of the positioning sleeve, the fan is installed on the positioning plate through bolts, the steam cooling device comprises an exchange envelope, a purpose-built piston, an exchange motor and a bearing plate, an outer side wall of the exchange envelope is connected with an outlet check valve through a pipeline, and an outer side of the exchange envelope, an exchange cavity is arranged in one end of the exchange envelope, a guide slide way is arranged on the side wall of one end of the exchange cavity in a penetrating manner, a piston head is arranged on the special piston, a piston rod is welded on one side of the piston head, a positioning groove is arranged on the side wall of the other end of the piston head, a laser emitter and a power regulator are sleeved in the positioning groove, the power regulator is connected with the laser emitter through a wire, the special piston is arranged in the exchange envelope through the matching of the piston head and the exchange cavity, an exchange rotating shaft is arranged on the exchange motor, a rotating disc is sleeved at one end of the exchange rotating shaft, an eccentric rotating shaft is arranged on one side of the rotating disc, the other end of the piston rod penetrates through the guide slide way and is connected with the eccentric rotating shaft through a connecting plate, the particle damping device comprises a, the filter rotary table cover is established and is located one side of filter in crossing the water sleeve, it is provided with the low-speed pivot to cross on the water motor, it has seted up the mating holes to run through on the telescopic one end lateral wall of water, it is provided with out the water swivel to cross the telescopic other end of water, the one end of low-speed pivot runs through the mating holes and is connected with the filter rotary table, be provided with control button on the control electronic box.

In a preferred embodiment of the present invention, the outlet check valve is connected to the inlet pipe through a pipeline, and the inlet check valve is connected to the exhaust pipe through a pipeline.

As a preferred embodiment of the present invention, the exchange envelope and the exchange motor are mounted on the top side wall of the bearing plate by bolts, and the bearing plate is mounted on the top side wall of the wind shield by bolts.

As a preferred embodiment of the present invention, an air passing channel is formed through one side of the mixing box, heat dissipation square tubes are uniformly arranged in the air passing channel, heat dissipation fins are arranged on the side wall of the mixing box at two sides of the air passing channel, and aluminum alloy nanoparticles are arranged in the mixing box.

As a preferred embodiment of the present invention, the delivery pump assembly comprises a water supply pump, a water supply motor and an acceleration pipe, the water supply motor is disposed at one side of the water supply pump, a water pumping pipe is disposed at one side of the air hood on the side wall of the mixing box, the water supply pump is provided with a water pumping port and a water discharge port, the water pumping port is connected to the water pumping pipe through a pipeline, and the water discharge port is connected to one end of the acceleration pipe through a pipeline.

In a preferred embodiment of the present invention, a spiral guide plate is disposed in the speed increasing pipe, and a water inlet joint is disposed at the other end of the speed increasing pipe.

In a preferred embodiment of the present invention, the filter turntable and the filter plate are provided with communication holes at one side thereof.

As a preferred embodiment of the present invention, the control buttons include a steam exchange button, a cooling button, a circulation button, a laser button, and a damping button, and the control buttons are connected to the exchange motor, the blower, the laser emitter, the water passing motor, and the water supply motor through wires.

Compared with the prior art, the invention has the beneficial effects that:

1. the aluminum alloy nano particles are arranged in the mixing box, and the aluminum alloy nano particles and water are mixed to form a nano hydrate, so that the mixed metal nano solution has high heat exchange efficiency and good heat dissipation effect due to the fact that the heat dissipation efficiency of the aluminum alloy is higher than that of water and the mobility of the nano particles is high;

2. the water in the radiator is in a circulating flow state, the filtering rotary disc and the filter plate on the particle damping device are both provided with eccentric communicating holes, the filtering rotary disc periodically realizes the state that the two communicating holes are communicated in the rotating process relative to the filter plate, when the two communicating holes are communicated, the aluminum alloy nano particles can circulate, when the two communicating holes are not communicated, the metal nano particles are filtered at one side of the water passing sleeve, and the water body can pass through the filtering rotary disc and the filter plate to continue to circulate, so that a large amount of accumulated aluminum alloy nano particles can absorb heat to the maximum extent;

3. the exchange motor utilizes an eccentric rotating shaft on a turntable to drive a piston rod to do reciprocating linear motion through a connecting plate, the volume in an exchange cavity is periodically changed to cause that a one-way valve can lead steam at the top in a mixing box into an exchange jacket, a one-way valve can lead low-temperature condensate water in the exchange cavity back to the mixing box, meanwhile, a laser emitter on a piston head can emit laser, and according to the principle of Doppler effect and atomic energy level quantization of light, the laser can cool down water molecules which move violently, so that the temperature of the steam is reduced, and the steam returns to the mixing box again, and the temperature of a radiator can be ensured to be in a small-range floating state.

Drawings

FIG. 1 is a schematic cross-sectional view of the present invention;

FIG. 2 is a schematic view of the structure of the heat dissipation box assembly of the present invention;

FIG. 3 is a cross-sectional structural schematic view of the mixing box of the present invention;

FIG. 4 is a schematic structural diagram of a steam cooling device according to the present invention;

FIG. 5 is a schematic diagram of the configuration of the exchange jacket and the tailored piston of the present invention;

FIG. 6 is a schematic view of the structure of the particle damping device of the present invention;

FIG. 7 is a schematic cross-sectional view of the speed increasing tube of the present invention;

in the figure: 1-chassis, 2-heat dissipation box combination, 3-steam cooling device, 4-delivery pump combination, 5-particle damping device, 6-control electric box, 7-mixing box, 8-exhaust pipe, 9-water inlet pipe, 10-fan cover, 11-positioning sleeve, 12-exchange envelope, 13-special piston, 14-exchange motor, 15-outlet one-way valve, 16-inlet one-way valve, 17-exchange cavity, 18-guide slideway, 19-piston head, 20-piston rod, 21-laser emitter, 22-connecting plate, 23-water passing sleeve, 24-filtering turntable, 25-water passing motor, 26-filter plate, 27-heat dissipation square tube, 28-water supply pump, 29-water supply motor, 30-speed increasing tube, 31-spiral guide plate, 32-water inlet joint, 33-fan, 34-rotary table, 35-aluminum alloy nano-particle and 36-bearing plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-7, the present invention provides a technical solution:

an energy-saving efficient nanometer mixed liquid sectional radiator comprises a chassis 1, a heat dissipation box combination 2, a steam cooling device 3, a delivery pump combination 4, a particle damping device 5 and a control electric box 6, wherein the heat dissipation box combination 2 comprises a mixing box 7 and a fan 33, the mixing box 7 is installed on the top side wall of the chassis 1 through bolts, a return pipe is arranged on the top side wall of the mixing box 7, one side of the mixing box 7 is provided with a steam exhaust pipe 8 and an inlet pipe 9 from top to bottom, one side of the mixing box 7 is provided with a fan cover 10, one end side wall of the fan cover 10 is provided with a positioning sleeve 11, a positioning plate is welded on the inner side wall of the positioning sleeve 11, the fan 33 is installed on the positioning plate through bolts, the steam cooling device 3 comprises an exchange envelope 12, a specially-made piston 13, an exchange motor 14 and a bearing plate 36, and one end side wall of the exchange envelope 12 is connected with a one, the outer side of the exchange jacket 12 is connected with a check valve 16 through a pipeline, an exchange cavity 17 is arranged inside one end of the exchange jacket 12, a guide slide way 18 penetrates through the side wall of one end of the exchange cavity 17, a piston head 19 is arranged on the purpose-made piston 13, a piston rod 20 is welded on one side of the piston head 19, a positioning groove is formed in the side wall of the other end of the piston head 19, a laser emitter 21 and a power regulator are sleeved in the positioning groove, the power regulator is connected with the laser emitter 21 through an electric wire, the purpose-made piston 13 is installed in the exchange jacket 12 through the matching of the piston head 19 and the exchange cavity 17, an exchange rotating shaft is arranged on the exchange motor 14, a rotating disc 34 is sleeved at one end of the exchange rotating shaft, an eccentric rotating shaft is arranged on one side of the rotating disc 34, and the other end of the piston rod, particle damping device 5 comprises crossing water sleeve 23, filtration carousel 24 and crossing water motor 25, it is provided with filter 26 on the water sleeve 23 inside wall to cross, it establishes in water sleeve 23 and is located one side of filter 26 to filter carousel 24 cover, it is provided with the low-speed pivot on the motor 25 to cross the water, it has seted up the mating holes to run through on the one end lateral wall of water sleeve 23, the other end of crossing water sleeve 23 is provided with out the water swivel, the one end of low-speed pivot runs through the mating holes and is connected with filtration carousel 24, be provided with control button on the control electronic box 6.

In a preferred embodiment of the present invention, the outlet check valve 15 is connected to the inlet pipe 9 through a pipeline, and the inlet check valve 16 is connected to the exhaust pipe 8 through a pipeline.

In a preferred embodiment of the present invention, the exchange jacket 12 and the exchange motor 14 are mounted on the top side wall of the bearing plate 36 by bolts, and the bearing plate 36 is mounted on the top side wall of the wind shield 10 by bolts.

As a preferred embodiment of the present invention, an air passing channel is formed through one side of the mixing box 7, the heat dissipation square pipes 27 are uniformly arranged in the air passing channel, the heat dissipation fins are arranged on the side wall of the mixing box 7 at two sides of the air passing channel, and the aluminum alloy nanoparticles 35 are arranged in the mixing box 7.

In a preferred embodiment of the present invention, the delivery pump assembly 4 comprises a water supply pump 28, a water supply motor 29 and a speed increasing pipe 30, the water supply motor 29 is disposed on one side of the water supply pump 28, a water pumping pipe is disposed on one side of the side wall of the mixing box 7, which is located on the air hood 10, the water supply pump 28 is provided with a water pumping port and a water discharging port, the water pumping port is connected to the water pumping pipe through a pipeline, and the water discharging port is connected to one end of the speed increasing pipe 30 through a pipeline.

In a preferred embodiment of the present invention, a spiral guide plate 31 is disposed in the speed increasing pipe 30, and a water inlet joint 32 is disposed at the other end of the speed increasing pipe 30.

In a preferred embodiment of the present invention, the filter rotating disc 24 and the filter plate 26 are provided with communication holes at one side thereof.

In a preferred embodiment of the present invention, the control buttons include a steam change button, a temperature reduction button, a circulation button, a laser button, and a damping button, and the control buttons are connected to the exchange motor 14, the blower 33, the laser emitter 21, the water passing motor 25, and the water supply motor 29 through electric wires.

The working principle is as follows: firstly, the control electric box 6 is connected with an external power supply through an electric wire, the external power supply supplies electric energy to the equipment, then the water inlet joint 32 at the end part of the speed increasing pipe 30 and one end of the water passing sleeve 23 are connected into the equipment or the machine needing cooling, then a proper amount of water is added into the mixing box 7, the water and the aluminum alloy nano particles 35 in the mixing box form hydrates, when the external equipment or the machine works, the circulation button is manually pressed, the water supply motor 29 is started to drive the water supply pump 28 to start, the hydrates in the mixing box 7 are conveyed into the external equipment or the machine under the guidance of the spiral guide plate 31 in the speed increasing pipe 30 without sediment, and then the hydrates are returned into the mixing box 7 through the particle damping device 5, so that a heat dissipation loop is formed, the water flow containing the aluminum alloy nano particles 35 enters the external equipment or the machine for heat exchange, and in order to maximize the, the damping button is manually pressed, the water passing motor 25 drives the filtering rotary disc 24 to rotate, the filter plate 26 and the filtering rotary disc 24 can filter and accumulate aluminum alloy nano particles 35 in external equipment or machines for absorbing heat, when the communication holes on the filter plate 26 and the filtering rotary disc 24 are overlapped, the aluminum alloy nano particles 35 containing a large amount of heat are conveyed back into the mixing box 7 through a pipeline, then the temperature reduction button is manually pressed, the fan 33 is started to carry out air cooling and heat dissipation on the mixing box 7 through the fan cover 10, when the water temperature in the mixing box 7 is high to form steam, the steam changing button and the laser button are manually pressed, the exchange motor 14 is started to drive the rotary disc 34 to rotate, the rotary disc 34 enables the piston rod 20 to drive the piston head 19 to reciprocate and linearly in the exchange cavity 17 through the connecting plate 22, the volume of the exchange cavity 17 is periodically changed, and therefore the steam in the mixing box 7 can enter the exchange cavity 17 through the one, then the steam is sent back to the mixing box 7 through the one-way valve 15, meanwhile, an external power supply supplies power to a laser emitter 21 in the piston head 19 through a power regulator, the laser starts to irradiate steam impacting oppositely, according to the principle of Doppler effect and atomic energy level quantization of light, the laser can inhibit the activity of water molecules, so that the temperature of the steam is reduced, the steam is further condensed into water, and then the water is sent back to the mixing box 7.

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

Claims

1. An energy-saving efficient nanometer mixed liquid sectional radiator is characterized in that: including chassis (1), heat dissipation case combination (2), steam cooling device (3), delivery pump combination (4), granule damping device (5) and control electronic box (6), heat dissipation case combination (2) comprises mixing box (7) and fan (33), mixing box (7) are installed on the top lateral wall of chassis (1) through the bolt, be provided with the back flow on the top lateral wall of mixing box (7), one side of mixing box (7) is from last to having set gradually exhaust pipe (8) and oral siphon (9) down, one side of mixing box (7) is provided with fan housing (10), be provided with position sleeve (11) on the one end lateral wall of fan housing (10), the welding has the locating plate on the inside wall of position sleeve (11), fan (33) are installed on the locating plate through the bolt, steam cooling device (3) are by exchanging big envelope (12), The special piston (13), the exchange motor (14) and the bearing plate (36) are formed, a one-way valve (15) is connected to the side wall of one end of the exchange jacket (12) through a pipeline, a one-way valve (16) is connected to the outer side of the exchange jacket (12) through a pipeline, an exchange cavity (17) is arranged inside one end of the exchange jacket (12), a guide slide way (18) is arranged on the side wall of one end of the exchange cavity (17) in a penetrating mode, a piston head (19) is arranged on the special piston (13), a piston rod (20) is welded to one side of the piston head (19), a positioning groove is formed in the side wall of the other end of the piston head (19), a laser emitter (21) and a power regulator are arranged in the positioning groove in a sleeved mode, the power regulator is connected with the laser emitter (21) through an electric wire, the special piston (13) is installed in the exchange jacket (12) through the, the particle damping device is characterized in that an exchange rotating shaft is arranged on the exchange motor (14), a rotating disc (34) is sleeved at one end of the exchange rotating shaft, an eccentric rotating shaft is arranged on one side of the rotating disc (34), the other end of the piston rod (20) penetrates through the guide slide way (18) and is connected with the eccentric rotating shaft through a connecting plate (22), the particle damping device (5) is composed of a water passing sleeve (23), a filtering rotating disc (24) and a water passing motor (25), a filtering plate (26) is arranged on the inner side wall of the water passing sleeve (23), the filtering rotating disc (24) is sleeved in the water passing sleeve (23) and is positioned on one side of the filtering plate (26), a low-speed rotating shaft is arranged on the water passing motor (25), a matching hole is formed in the side wall of one end of the water passing sleeve (23) in a penetrating manner, a water outlet joint is arranged at the other end of the water, and a control button is arranged on the control electric box (6).

2. The energy-saving efficient nano mixed liquid sectional radiator as claimed in claim 1, wherein: the outlet one-way valve (15) is connected with the water inlet pipe (9) through a pipeline, and the inlet one-way valve (16) is connected with the steam exhaust pipe (8) through a pipeline.

3. The energy-saving efficient nano mixed liquid sectional radiator as claimed in claim 1, wherein: the exchange envelope (12) and the exchange motor (14) are mounted on the top side wall of the bearing plate (36) through bolts, and the bearing plate (36) is mounted on the top side wall of the fan cover (10) through bolts.

4. The energy-saving efficient nano mixed liquid sectional radiator as claimed in claim 1, wherein: run through on one side of mixing box (7) and seted up the wind side way, evenly be provided with heat dissipation side pipe (27) in the wind side way, the both sides that lie in the wind side way on the lateral wall of mixing box (7) are provided with the fin, be provided with aluminum alloy nanoparticle (35) in mixing box (7).

5. The energy-saving efficient nano mixed liquid sectional radiator as claimed in claim 1, wherein: the utility model discloses a fan cover, including delivery pump combination (4), delivery pump (28), water supply motor (29) and acceleration rate pipe (30), water supply motor (29) set up the one side at delivery pump (28), one side that lies in fan cover (10) on mixing box (7) lateral wall is provided with the drinking-water pipe, be provided with on delivery pump (28) and draw water mouth and outlet, the mouth that draws water is through pipeline and pumping pipe connection, the one end connection of pipeline and acceleration rate pipe (30) is passed through in the outlet.

6. The energy-saving efficient nano mixed liquid sectional radiator as claimed in claim 1, wherein: a spiral guide plate (31) is arranged in the speed increasing pipe (30), and a water inlet joint (32) is arranged at the other end of the speed increasing pipe (30).

7. The energy-saving efficient nano mixed liquid sectional radiator as claimed in claim 1, wherein: one side of the filtering turntable (24) and one side of the filtering plate (26) are both provided with communicating holes in a penetrating way.

8. The energy-saving efficient nano mixed liquid sectional radiator as claimed in claim 1, wherein: the control button comprises a steam exchange button, a cooling button, a circulation button, a laser button and a damping button, and is connected with the exchange motor (14), the fan (33), the laser emitter (21), the water passing motor (25) and the water supply motor (29) through electric wires.