CN215404596U - Aluminium magnesium alloy micro-arc electrophoresis has solidification equipment of energy-conserving structure - Google Patents

Abstract

The utility model discloses an aluminum-magnesium alloy micro-arc electrophoresis curing device with an energy-saving structure, which comprises a curing chamber, wherein one side of the curing chamber is provided with an air inlet, one side of the air inlet is connected with an air inlet pipe, one end of the air inlet pipe is connected with an electric heating piece heating device, the inner wall of the curing chamber is provided with a temperature sensor, the outer wall of the electric heating piece heating device is provided with a temperature controller, the other side of the curing chamber is provided with an air return opening, the bottom of the air return opening is connected with an air return pipe, one end of the air return pipe is connected with a heat exchanger, a sterilization filter is arranged above the heat exchanger, one side of the sterilization filter is connected with a blower, a filter screen frame is arranged inside the sterilization filter, a filter screen is connected above the filter screen frame, the bottom of the filter screen is connected with an air inlet, and the bottom of the filter screen is connected with an air outlet; the solidification device with the energy-saving structure for the aluminum-magnesium alloy micro-arc electrophoresis can achieve the effects of small environmental pollution and energy saving by arranging the heat exchanger and the electric heating piece heating device.

Description

Aluminium magnesium alloy micro-arc electrophoresis has solidification equipment of energy-conserving structure

Technical Field

The utility model relates to the technical field of curing furnaces, in particular to a curing device with an energy-saving structure for aluminum-magnesium alloy micro-arc electrophoresis.

Background

The curing mainly refers to the production process of heating, resin curing and drying parts in order to enhance the stress of material combination in the electronic industry and other various industries. The curing oven is the curing container.

The prior art has the following defects or problems:

1. the existing curing device has low efficiency in the process of drying cured substances, and a large amount of energy loss causes waste;

2. the direct discharge of hot gas during the curing process has certain influence on the environment.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a solidification device with an energy-saving structure for aluminum magnesium alloy micro-arc electrophoresis aiming at the defects in the prior art so as to solve the problems in the background art.

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

the utility model provides an almag micro arc electrophoresis has solidification equipment of energy-conserving structure, includes the curing chamber, the air intake has been seted up to one side of curing chamber, one side of air intake is connected with the air-supply line, the one end of air-supply line is connected with electric heat piece heating device, the inner wall of curing chamber is provided with temperature sensor, electric heat piece heating device's outer wall is provided with the temperature controller, the opposite side of curing chamber has seted up the return air inlet, the bottom of return air inlet is connected with the return air hose, the one end of return air hose is connected with the heat exchanger, the top of heat exchanger is provided with the degerming filter, one side of degerming filter is connected with the forced draught blower, the inside of degerming filter is provided with the screen frame, the screen frame top is connected with the filter screen, the bottom of screen frame is connected with the air inlet, the bottom of screen frame is connected with the gas outlet, one side outer wall of heat exchanger has seted up fluid inlet, and a fluid outlet is formed in the outer wall of the other side of the heat exchanger.

As a preferred technical scheme of the utility model, four groups of air inlets are provided, four groups of air inlets are movably connected with an air inlet pipe through pipelines, four groups of air return inlets are provided, and four groups of air return inlets are movably connected with an air return pipe through pipelines.

As a preferred technical scheme of the utility model, a signal output end of the temperature sensor is electrically connected with a signal input end of the temperature controller, a signal output end of the temperature controller is electrically connected with the input end of the electric heating sheet heating device, and an air outlet of the electric heating sheet heating device is movably connected with the air inlet pipe through a pipeline.

As a preferred technical scheme of the utility model, the filter screen is fixedly connected with the filter screen frame through bolts, the air outlet of the blower is movably connected with the air inlet through a pipeline, and the air outlet is movably connected with the air inlet of the electric heating piece heating device through a pipeline.

As a preferred technical scheme of the utility model, the two groups of fluid inlets are respectively a cold fluid inlet and a hot fluid inlet, the two groups of fluid outlets are respectively a cold fluid outlet and a hot fluid outlet.

As a preferable technical scheme of the utility model, a hot fluid inlet of the fluid inlet is movably connected with the air return pipe through a pipeline, and a hot fluid outlet of the fluid outlet is movably connected with the air inlet through a pipeline.

Compared with the prior art, the utility model provides a solidification device with an energy-saving structure for aluminum-magnesium alloy micro-arc electrophoresis, which has the following beneficial effects:

1. this aluminium-magnesium alloy micro arc electrophoresis has solidification equipment of energy-conserving structure, through the air outlet at the forced draught blower connects the bacteria removal filter, can filter the air that the forced draught blower sent into, can make the purity of the gas that gets into the solidification room, prolong the life-span of solidification room, connect the electric heat piece heating device at the gas outlet of bacteria removal filter, can heat the gas that sends into the solidification room, accelerate the solidification speed, through setting up temperature sensor, can detect the temperature transmission of solidification room and give the temperature controller, when the solidification room temperature reaches the solidification requirement, the temperature controller suitably reduces the temperature of electric heat piece heating device, so as to reduce the use of electric power;

2. this aluminium magnesium alloy micro arc electrophoresis has solidification equipment of energy-conserving structure, hot-fluid import through the end-to-end connection heat exchanger at the return-air duct, can exchange heat from the cold fluid export outflow with the cold air that gets into through the cold fluid import, the gas temperature greatly reduced who gets rid of like this, the pollution to the environment has been reduced, the steam of hot-fluid export passes through the pipeline and gets into the air inlet, get into electric heat piece heating device entering solidification chamber from the gas outlet through the filter screen, form a circulation, the thermal loss has been reduced, there is better energy-conserving effect.

Drawings

FIG. 1 is a schematic view of the overall structure of a curing device with an energy-saving structure for aluminum-magnesium alloy micro-arc electrophoresis according to the present invention;

FIG. 2 is a schematic structural diagram of a sterilizing filter of a curing device with an energy-saving structure for aluminum-magnesium alloy micro-arc electrophoresis according to the present invention;

FIG. 3 is a schematic diagram of a heat exchanger of a solidification device with an energy-saving structure for aluminum-magnesium alloy micro-arc electrophoresis according to the present invention.

In the figure: 1. a curing chamber; 2. an air inlet; 3. an air inlet pipe; 4. an electric heating plate heating device; 5. a temperature sensor; 6. a temperature controller; 7. an air return opening; 8. a return air duct; 9. a heat exchanger; 10. a sterilizing filter; 11. a blower; 12. a screen frame; 13. a filter screen; 14. an air inlet; 15. an air outlet; 16. a fluid inlet; 17. a fluid outlet.

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. 1-3, in this embodiment:

an aluminum-magnesium alloy micro-arc electrophoresis curing device with an energy-saving structure comprises a curing chamber 1, one side of the curing chamber 1 is provided with an air inlet 2, one side of the air inlet 2 is connected with an air inlet pipe 3, one end of the air inlet pipe 3 is connected with an electric heating piece heating device 4, the inner wall of the curing chamber 1 is provided with a temperature sensor 5, the outer wall of the electric heating piece heating device 4 is provided with a temperature controller 6, the other side of the curing chamber 1 is provided with an air return opening 7, the bottom of the air return opening 7 is connected with an air return pipe 8, one end of the air return pipe 8 is connected with a heat exchanger 9, a sterilizing filter 10 is arranged above the heat exchanger 9, one side of the sterilizing filter 10 is connected with a blower 11 with the type GDFJ-150, a filter screen frame 12 is arranged inside the sterilizing filter 10, a filter screen 13 is connected above the filter screen 12, the bottom of the filter screen 13 is connected with an air inlet 14, and the bottom of the filter screen 13 is connected with an air outlet 15, the outer wall of one side of the heat exchanger 9 is provided with a fluid inlet 16, and the outer wall of the other side of the heat exchanger 9 is provided with a fluid outlet 17.

In the embodiment, four air inlets 2 are provided, four air inlets 2 are movably connected with the air inlet pipe 3 through a pipeline, four air return inlets 7 are provided, and four air return inlets 7 are movably connected with the air return pipe 8 through a pipeline, so that the air entering the curing chamber 1 can meet the requirement of the curing chamber 1, and meanwhile, redundant gas can be timely discharged; the signal output end of the temperature sensor 5 is electrically connected with the signal input end of the temperature controller 6, the signal output end of the temperature controller 6 is electrically connected with the input end of the electric heating sheet heating device 4, the air outlet of the electric heating sheet heating device 4 is movably connected with the air inlet pipe 3 through a pipeline, the electric heating sheet heating device 4 heats the gas entering the curing chamber 1, and the temperature of the curing chamber 1 can meet the curing requirement; the filter screen 13 is fixedly connected with the filter screen frame 12 through bolts, the air outlet of the blower 11 is movably connected with the air inlet 14 through a pipeline, so that the gas entering the curing chamber 1 is purer, the curing effect is improved, and the air outlet 15 is movably connected with the air inlet of the electric heating sheet heating device 4 through a pipeline; two groups of fluid inlets 16 are provided, the two groups of fluid inlets 16 are respectively a cold fluid inlet and a hot fluid inlet, the two groups of fluid outlets 17 are provided, and the two groups of fluid outlets 17 are respectively a cold fluid outlet and a hot fluid outlet, so that heat exchange of cold and hot gases can be better completed; a hot fluid inlet of the fluid inlet 16 is movably connected with the air return pipe 8 through a pipeline, a hot fluid outlet of the fluid outlet 17 is movably connected with the air inlet 14 through a pipeline to ensure that the discharged air is cold air, so that the pollution to the environment is reduced, and the gas entering the air inlet 14 is hot air, so that the loss of heat is reduced.

The working principle and the using process of the utility model are as follows: when the user uses the device, firstly, the air outlet of the blower 11 is connected with the air inlet 14 of the sterilizing filter 10 through a pipeline, the air outlet 15 is connected with the air inlet of the electric heating sheet heating device 4 through a pipeline, then, the air outlet of the electric heating sheet heating device 4 is connected with the air inlet pipe 3, air enters the curing chamber 1 through the air inlet 2 to cure objects, then enters the air return pipe 8 through the air return opening 7, enters the heat exchanger 9 through the hot fluid inlet of the fluid inlet 16, then flows out of the chamber from the cold fluid outlet of the fluid outlet 17 or enters the air inlet 14 of the sterilizing filter 10 from the hot fluid outlet, enters the electric heating sheet heating device 4 from the air outlet 15 through the filtration of the filter screen 13 to form a hot air circulation, so that the heat loss is reduced, the temperature sensor 5 in the curing chamber 1 monitors the temperature in real time, when the temperature of the curing chamber 1 is too high, the temperature controller 6 can reduce the temperature of the electric heating piece heating device 4, reduce the use of electric power and achieve better energy-saving effect.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that changes may be made in the embodiments and/or equivalents thereof without departing from the spirit and scope of the utility model. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (6)

1. The utility model provides an almag micro arc electrophoresis has solidification equipment of energy-conserving structure which characterized in that: comprises a curing chamber (1), an air inlet (2) is arranged on one side of the curing chamber (1), an air inlet pipe (3) is connected on one side of the air inlet (2), an electric heating piece heating device (4) is connected with one end of the air inlet pipe (3), a temperature sensor (5) is arranged on the inner wall of the curing chamber (1), a temperature controller (6) is arranged on the outer wall of the electric heating piece heating device (4), an air return port (7) is arranged on the other side of the curing chamber (1), an air return pipe (8) is connected with the bottom of the air return port (7), a heat exchanger (9) is connected with one end of the air return pipe (8), a sterilizing filter (10) is arranged above the heat exchanger (9), a blower (11) is connected with one side of the sterilizing filter (10), and a filter screen frame (12) is arranged inside the sterilizing filter (10), filter screen frame (12) top is connected with filter screen (13), the bottom of filter screen (13) is connected with air inlet (14), the bottom of filter screen (13) is connected with gas outlet (15), fluid inlet (16) have been seted up to one side outer wall of heat exchanger (9), fluid outlet (17) have been seted up to the opposite side outer wall of heat exchanger (9).

2. The solidification equipment with energy-saving structure for aluminum magnesium alloy micro-arc electrophoresis according to claim 1, wherein: the air inlet (2) is provided with four groups, the four groups of air inlets (2) are movably connected with the air inlet pipe (3) through pipelines, the four groups of air return ports (7) are provided, and the four groups of air return ports (7) are movably connected with the air return pipe (8) through pipelines.

3. The solidification equipment with energy-saving structure for aluminum magnesium alloy micro-arc electrophoresis according to claim 1, wherein: the signal output end of the temperature sensor (5) is electrically connected with the signal input end of the temperature controller (6), the signal output end of the temperature controller (6) is electrically connected with the good input end of the electric heating piece heating device (4), and the air outlet of the electric heating piece heating device (4) is movably connected with the air inlet pipe (3) through a pipeline.

4. The solidification equipment with energy-saving structure for aluminum magnesium alloy micro-arc electrophoresis according to claim 1, wherein: filter screen (13) are through bolt and filter screen frame (12) fixed connection, the air outlet of forced draught blower (11) passes through pipeline and air inlet (14) swing joint, air outlet (15) pass through the air intlet swing joint of pipeline and electric heat piece heating device (4).

5. The solidification equipment with energy-saving structure for aluminum magnesium alloy micro-arc electrophoresis according to claim 1, wherein: the two groups of fluid inlets (16) are respectively cold fluid inlets and hot fluid inlets, the two groups of fluid outlets (17) are respectively cold fluid outlets and hot fluid outlets, and the two groups of fluid outlets (17) are respectively cold fluid outlets and hot fluid outlets.

6. The solidification equipment with energy-saving structure for aluminum magnesium alloy micro-arc electrophoresis according to claim 1, wherein: a hot fluid inlet of the fluid inlet (16) is movably connected with the air return pipe (8) through a pipeline, and a hot fluid outlet of the fluid outlet (17) is movably connected with the air inlet (14) through a pipeline.

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