CN112268334A

CN112268334A - Built-in ultraviolet disinfection device of ventilation system

Info

Publication number: CN112268334A
Application number: CN202011188581.8A
Authority: CN
Inventors: 罗亦鸣; 李恩友
Original assignee: Nanjing Jielide Environmental Protection Technology Co Ltd
Current assignee: Shengyida (Chengdu) Optoelectronic Technology Co.,Ltd.
Priority date: 2020-10-30
Filing date: 2020-10-30
Publication date: 2021-01-26

Abstract

The invention discloses a ventilation system built-in ultraviolet disinfection device, which comprises a ventilation pipeline, at least two airflow power generation devices and a disinfection system, wherein the ventilation pipeline is internally provided with the airflow power generation devices; the disinfection system is an ultraviolet lamp and is arranged in the ventilation pipeline, and the ultraviolet lamp is connected with the voltage output end of the generator in the ventilation pipeline; the invention improves the working efficiency, reduces the working cost, is safe and stable, and is efficient and energy-saving.

Description

Built-in ultraviolet disinfection device of ventilation system

Technical Field

The invention relates to the technical field of sterilization and disinfection equipment, in particular to a built-in ultraviolet disinfection device of a ventilation system.

Background

Ultraviolet lamp is widely used in air disinfection equipment, but among the prior art, ultraviolet disinfection equipment applied to ventilation systems such as central air conditioning can only work by being powered by an external power supply, and once the power supply of the ultraviolet lamp is turned off due to faults or misoperation of operators and the like, air in a ventilation pipeline can enter a room without being disinfected, so that respiratory diseases are easily transmitted. In addition, the existing air duct type ultraviolet lamp disinfection system is usually provided with an air quantity sensor, and the system is started when obvious gas flows in a channel, so that the work in unnecessary time, the energy waste and the service life of an ultraviolet lamp tube are avoided. However, the additional air volume sensor also increases the cost and control complexity of the system.

In order to save energy, simplify design, improve working efficiency, save time and save labor, the invention provides a ventilation system built-in ultraviolet disinfection device.

Disclosure of Invention

The invention aims to solve the technical problem that an ultraviolet disinfection device is arranged in a ventilation system, and the ultraviolet disinfection device is provided with an airflow power generation device, can supply power by using airflow and does not need external energy. And the airflow generator can play the role of an air volume sensor at the same time, and only when the airflow in the air duct obviously flows, enough electric power can be generated to drive the ultraviolet disinfection device to work, so that the useless work of the ultraviolet disinfection system when the ventilation system does not work can be avoided. The ultraviolet disinfection device can save energy, simplify system design, improve working efficiency and reduce system cost.

The technical scheme for solving the technical problems is as follows:

a ventilation system built-in ultraviolet disinfection device comprises a ventilation pipeline, at least two airflow power generation devices and a disinfection system, wherein the airflow power generation devices are arranged in the ventilation pipeline, each airflow power generation device comprises a shell, an air opening is formed in the front end of each shell, a wind power moving blade is arranged at the front end of each shell, and the rear end of each wind power moving blade is sequentially connected with an air compressor and a generator; the disinfection system is an ultraviolet lamp and is arranged inside the ventilation pipeline, and the ultraviolet lamp is connected with the voltage output end of the generator in the ventilation pipeline.

The technical scheme of the invention is further defined as follows:

the ventilation system is internally provided with the ultraviolet disinfection device, and the heat dissipation holes are paved on the shell.

Aforementioned built-in ultraviolet ray degassing unit of ventilation system, the air compressor machine is birotor frequency conversion compressor, and built-in there is the power house in birotor frequency conversion compressor's the host computer shell, is equipped with the screw rod pivot in the power house, and the admission valve is connected to the one end of screw rod pivot, and the other end of screw rod pivot is connected with the shaft coupling through the connecting hole on the host computer shell, and the screw rod pivot includes positive rotor and negative rotor, and positive rotor, the negative rotor in the screw rod pivot are opposite state and set up.

In the ultraviolet disinfection device arranged in the ventilation system, the inside and the outside of the shell are coated with the high-temperature-resistant coating, and the high temperature resistance is realized by the following two components: b =4:1.5, wherein the A and B comprise the following components in parts by mass:

the component A comprises the following components in parts by weight: silicone rubber: 3-8 parts of hydroxyethyl cellulose: 11-14 parts of talcum powder: 9-13 parts of dispersant: 8-14 parts of zinc oxide: 7-12 parts of color master batch: 20-24 parts of filler: 19-24 parts of a plasticizer: 10-13 parts of a film-forming additive: 14-18 parts of defoaming agent: 3-8 parts;

the component B comprises the following components in parts by mass: calcium stearate: 7-14 parts of graphite: 6-8 parts of xylene: 1-4 parts of nano silicon dioxide powder: 22-27 parts of plasticizing resin: 15-19 parts of vapor phase corrosion inhibitor: 17-19 parts of a heat stabilizer: 10-14 parts of methyl methacrylate: 8-10 parts of coupling agent: 11-18 parts of flame retardant: 25-29 parts.

In the ultraviolet disinfection device arranged in the ventilation system, the dispersant is one of sodium tripolyphosphate, sodium tetrapolyphosphate or sodium hexametaphosphate; the filler is glass flakes; the plasticizer is one of dioctyl phthalate, tricresyl phosphate or dibutyl phthalate; the film forming auxiliary agent is one of ethylene glycol ethyl ether, ethylene glycol butyl ether, ethylene glycol or propylene glycol; the defoaming agent is one or a mixture of more of organic silicon, polyether or amide; the heat stabilizer is one of oxidative dehydrochlorination, dibasic lead stearate or dibasic lead phthalate; the coupling agent is one of silane coupling agent or zirconium coupling agent; the flame retardant is phosphoric triester.

the component A comprises the following components in parts by weight: silicone rubber: 3 parts, hydroxyethyl cellulose: 11 parts, talc powder: 9 parts, dispersant: 8 parts, zinc oxide: 7 parts of color master batch: 20 parts of filler: 19 parts, plasticizer: 10 parts, film-forming assistant: 14 parts, defoaming agent: 3 parts of a mixture;

the component B comprises the following components in parts by mass: calcium stearate: 7 parts of graphite: 6 parts of xylene: 1 part, nano silicon dioxide powder: 22 parts, plasticizing resin: 15 parts of vapor phase corrosion inhibitor: 17 parts, heat stabilizer: 10 parts, methyl methacrylate: 8 parts, coupling agent: 11 parts, flame retardant: and 25 parts.

the component A comprises the following components in parts by weight: silicone rubber: 8 parts, hydroxyethyl cellulose: 14 parts, talc: 13 parts, dispersant: 14 parts of zinc oxide: 12 parts of color master batch: 24 parts of filler: 24 parts, plasticizer: 13 parts, film-forming aid: 18 parts, defoaming agent: 8 parts of a mixture;

the component B comprises the following components in parts by mass: calcium stearate: 14 parts of graphite: 8 parts, xylene: 4 parts of nano silicon dioxide powder: 27 parts, plasticizing resin: 19 parts of vapor phase corrosion inhibitor: 19 parts, heat stabilizer: 14 parts, methyl methacrylate: 10 parts, coupling agent: 18 parts, flame retardant: 29 parts.

the component A comprises the following components in parts by weight: silicone rubber: 5 parts, hydroxyethyl cellulose: 12 parts, talc powder: 11 parts, dispersant: 13 parts, zinc oxide: 10 parts of color master batch: 22 parts of filler: 23 parts, plasticizer: 11 parts, film-forming aid: 16 parts, defoaming agent: 5 parts of a mixture;

the component B comprises the following components in parts by mass: calcium stearate: 12 parts of graphite: 7 parts of xylene: 3 parts of nano silicon dioxide powder: 25 parts, plasticizing resin: 17 parts of vapor phase corrosion inhibitor: 18 parts, heat stabilizer: 12 parts, methyl methacrylate: 9 parts, coupling agent: 14 parts, flame retardant: 26 parts of (A).

According to the technical scheme of the invention: according to the technical scheme of the invention: in the invention, wind energy is converted into electric energy to drive the ultraviolet disinfection device, so that energy is saved, and disinfection failure caused by closing the power supply of the ultraviolet lamp by manual misoperation can be avoided; the airflow generating device replaces an air quantity sensor, ensures that the disinfection system can work only in a ventilation state, simplifies the design, saves the cost and improves the reliability of the system. The air compressor adopts a double-rotor design, so that the working efficiency is improved, the time and the labor are saved, and the efficiency and the energy are high; the outer coating of shell has high temperature resistant coating for the device is more durable, has prolonged the life of device, has reduced manufacturing cost.

Drawings

FIG. 1 and FIG. 2 are schematic structural views of the present invention;

FIG. 3 is a detail view of the air compressor of the present invention;

the wind power generation system comprises a ventilating duct 1, a shell 2, a wind power moving blade 3, an air compressor 4, a generator 5, an ultraviolet lamp 6, heat dissipation holes 8, a main machine shell 9, a power chamber 10, a screw rotating shaft 11, a male rotor 12 and a female rotor 13.

Detailed Description

Example 1

The embodiment provides a ventilation system built-in ultraviolet disinfection device, which comprises a ventilation pipeline 1, two airflow power generation devices and a disinfection system, wherein the ventilation pipeline 1 is internally provided with the two airflow power generation devices, each airflow power generation device comprises a shell 2, the front end of the shell 2 is an air opening and is provided with a wind power moving blade 3, and the rear end of the wind power moving blade 3 is sequentially connected with an air compressor 4 and a generator 5; the disinfection system is an ultraviolet lamp 6 and is arranged inside the ventilation pipeline 1, and the ultraviolet lamp 6 is connected with the voltage output end of the generator in the ventilation pipeline 1; the heat dissipation holes 8 are laid on the shell 2; the air compressor 4 is a double-rotor variable frequency compressor, a power chamber 10 is arranged in a main machine shell 9 of the double-rotor variable frequency compressor, a screw rotating shaft 11 is arranged in the power chamber, one end of the screw rotating shaft 11 is connected with an air inlet valve, the other end of the screw rotating shaft 11 is connected with a coupler through a connecting hole in the main machine shell 9, the screw rotating shaft 11 comprises a male rotor 12 and a female rotor 13, and the male rotor 12 and the female rotor 13 in the screw rotating shaft 11 are arranged in an opposite state;

the shell is internally and externally coated with a high-temperature-resistant coating, and the high temperature resistance is formed by mixing a component A and a component B: b =4:1.5, wherein the A and B comprise the following components in parts by mass:

the component B comprises the following components in parts by mass: calcium stearate: 7 parts of graphite: 6 parts of xylene: 1 part, nano silicon dioxide powder: 22 parts, plasticizing resin: 15 parts of vapor phase corrosion inhibitor: 17 parts, heat stabilizer: 10 parts, methyl methacrylate: 8 parts, coupling agent: 11 parts, flame retardant: 25 parts of (1);

the dispersant is one of sodium tripolyphosphate, tetrapolyphosphate or sodium hexametaphosphate; the filler is glass flakes; the plasticizer is one of dioctyl phthalate, tricresyl phosphate or dibutyl phthalate; the film forming auxiliary agent is one of ethylene glycol ethyl ether, ethylene glycol butyl ether, ethylene glycol or propylene glycol; the defoaming agent is one or a mixture of more of organic silicon, polyether or amide; the heat stabilizer is one of oxidative dehydrochlorination, dibasic lead stearate or dibasic lead phthalate; the coupling agent is one of silane coupling agent or zirconium coupling agent; the flame retardant is phosphoric triester.

Example 2

the component B comprises the following components in parts by mass: calcium stearate: 14 parts of graphite: 8 parts, xylene: 4 parts of nano silicon dioxide powder: 27 parts, plasticizing resin: 19 parts of vapor phase corrosion inhibitor: 19 parts, heat stabilizer: 14 parts, methyl methacrylate: 10 parts, coupling agent: 18 parts, flame retardant: 29 parts;

Example 3

the component B comprises the following components in parts by mass: calcium stearate: 12 parts of graphite: 7 parts of xylene: 3 parts of nano silicon dioxide powder: 25 parts, plasticizing resin: 17 parts of vapor phase corrosion inhibitor: 18 parts, heat stabilizer: 12 parts, methyl methacrylate: 9 parts, coupling agent: 14 parts, flame retardant: 26 parts of (1);

In addition to the above embodiments, the present invention may have other embodiments. All technical solutions formed by adopting equivalent substitutions or equivalent transformations fall within the protection scope of the claims of the present invention.

Claims

1. The utility model provides a built-in ultraviolet disinfection device of ventilation system, includes air pipe (1), air current power generation facility and disinfection system, its characterized in that: the ventilation pipeline (1) is internally provided with at least two airflow power generation devices, each airflow power generation device comprises a shell (2), the front end of each shell (2) is provided with an air opening and a wind power moving blade (3), and the rear end of each wind power moving blade (3) is sequentially connected with an air compressor (4) and a generator (5); the disinfection system be ultraviolet lamp (6) just the disinfection system locate inside air pipe (1), ultraviolet lamp (6) be connected with the voltage output of the generator in air pipe (1).

2. The ultraviolet sterilizer provided in a ventilation system according to claim 1, wherein: the shell (2) is paved with heat dissipation holes (8).

3. The ultraviolet sterilizer provided in a ventilation system according to claim 1, wherein: air compressor machine (4) be birotor frequency conversion compressor, birotor frequency conversion compressor's host computer shell (9) in built-in have power house (10), be equipped with screw rod pivot (11) in the power house, the admission valve is connected to the one end of screw rod pivot (11), the other end of screw rod pivot (11) is connected with the shaft coupling through the connecting hole on host computer shell (9), screw rod pivot (11) are including positive rotor (12) and cloudy rotor (13), positive rotor (12), cloudy rotor (13) in screw rod pivot (11) are the opposite state setting.

4. The ultraviolet sterilizer provided in a ventilation system according to claim 1, wherein: the shell (2) is internally and externally coated with a high-temperature-resistant coating, and the high temperature resistance is formed by mixing two components A and B according to the ratio of A: b =4:1.5, wherein the component A and the component B comprise the following components in parts by mass:

5. The ultraviolet sterilizer provided in a ventilation system according to claim 4, wherein: the dispersing agent is one of sodium tripolyphosphate, tetrapolyphosphate or sodium hexametaphosphate; the filler is glass flakes; the plasticizer is one of dioctyl phthalate, tricresyl phosphate or dibutyl phthalate; the film-forming auxiliary agent is one of ethylene glycol ethyl ether, ethylene glycol butyl ether, ethylene glycol or propylene glycol; the defoaming agent is one or a mixture of more of organic silicon, polyether or amide; the heat stabilizer is one of oxidative dehydrochlorination, dibasic lead stearate or dibasic lead phthalate; the coupling agent is one of silane coupling agent or zirconium coupling agent; the flame retardant is phosphoric triester.

6. The ultraviolet sterilizer provided in a ventilation system according to claim 4, wherein: the shell (2) is internally and externally coated with a high-temperature-resistant coating, and the high temperature resistance is formed by mixing two components A and B according to the ratio of A: b =4:1.5, wherein the component A and the component B comprise the following components in parts by mass:

7. The ultraviolet sterilizer provided in a ventilation system according to claim 4, wherein: the shell (2) is internally and externally coated with a high-temperature-resistant coating, and the high temperature resistance is formed by mixing two components A and B according to the ratio of A: b =4:1.5, wherein the component A and the component B comprise the following components in parts by mass:

8. The ultraviolet sterilizer provided in a ventilation system according to claim 4, wherein: the shell (2) is internally and externally coated with a high-temperature-resistant coating, and the high temperature resistance is formed by mixing two components A and B according to the ratio of A: b =4:1.5, wherein the component A and the component B comprise the following components in parts by mass: