CN210313540U - Vertical air-cooled ozone generator for integrated machine for sterilizing and cleaning waterline - Google Patents

Abstract

The utility model provides a waterline disinfects and washs vertical forced air cooling ozone generator for all-in-one, include: the ionization chamber comprises a shell, wherein an ionization sleeve is arranged in the shell, an upper partition plate and a lower partition plate are arranged in the ionization sleeve, and a sleeve is arranged between the upper partition plate and the lower partition plate; the sleeve is internally provided with the inner electrodes, and the same sides of the plurality of inner electrodes are connected through the insulating tapes; the upper end of the ionization sleeve is provided with an air inlet sleeve, the lower end of the ionization sleeve is provided with an air outlet sleeve, one end of the sleeve extends into the air inlet sleeve, and the other end of the sleeve extends into the air outlet sleeve; the upper clapboard is positioned at the outer edge of the air inlet sleeve and is provided with upper air holes, and the lower clapboard is positioned at the outer edge of the air outlet sleeve and is provided with lower air holes; the lower end of the shell is provided with a cooling gas inlet pipe, the upper end of the shell is provided with a cooling gas outlet pipe, oxygen enters from the gas inlet sleeve, and the sleeve and the ionization sleeve are integrally formed, and the plurality of inner electrodes adopt one outer electrode, so that the structure is simple and the installation is convenient; the surrounding area of the ionization sleeve is cooled through cooling gas, so that dead corners are avoided in cooling, and the cooling effect is good.

Description

Vertical air-cooled ozone generator for integrated machine for sterilizing and cleaning waterline

Technical Field

The utility model belongs to the technical field of the sterilizing installation technique and specifically relates to a waterline is disinfected and is washd vertical forced air cooling ozone generator of all-in-one.

Background

At present, ozone is generally produced in a mode of ionizing oxygen by high-voltage discharge during preparation, electrodes are installed in an ozone generator, and high-purity oxygen is introduced between the electrodes, so that the electrodes are utilized to ionize the oxygen to generate ozone. However, a large amount of heat is generated during the ionization process, and ozone is easily reduced to oxygen at a high temperature, thereby reducing the ozone production efficiency. The traditional ozone generator generally adopts an air cooling mode, namely a fan is adopted to ventilate the ozone generator, but the mode is complex to install, and has high heat dissipation efficiency and energy consumption; and the electrode has a cooling dead angle, and the heat radiation of the fan cannot be received in the dead angle, so that the heat radiation efficiency is reduced.

SUMMERY OF THE UTILITY MODEL

The utility model provides a waterline disinfects and washs vertical forced air cooling ozone generator for all-in-one, simple structure, simple to operate to utilize cooling gas to cool off the electrode, ozone preparation is efficient.

The technical scheme of the utility model is realized like this:

waterline disinfects and washs vertical forced air cooling ozone generator for all-in-one, include: the ionization device comprises a shell, wherein an ionization sleeve which is vertically arranged is arranged in the shell, the ionization sleeve is connected with a high-voltage electrode, a hollow cavity is arranged in the ionization sleeve, an upper partition plate and a lower partition plate are arranged in the hollow cavity, a plurality of vertical sleeves are arranged between the upper partition plate and the lower partition plate, and the sleeves and the ionization sleeve are integrally formed; an inner electrode is arranged in each sleeve, and the same sides of a plurality of inner electrodes are connected together through an insulating belt;

the upper end of the ionization sleeve is provided with an air inlet sleeve, the lower end of the ionization sleeve is provided with an air outlet sleeve, and the air outlet sleeve and the air inlet sleeve both extend to the outside of the shell; one end of the sleeve extends into the air inlet sleeve, and the other end of the sleeve extends into the air outlet sleeve;

the upper clapboard is provided with upper air holes which are positioned at the outer edge of the air inlet sleeve; the lower clapboard is provided with a lower air vent which is positioned at the outer edge of the air outlet sleeve;

the lower end of the shell is provided with a cooling gas inlet pipe communicated with cooling gas, and the upper end of the shell is provided with a cooling gas outlet pipe.

As an improvement mode, a flow equalizing plate is arranged in the air inlet sleeve, and a plurality of flow equalizing holes are formed in the flow equalizing plate.

As an improved mode, an upper mounting groove matched with the air inlet sleeve is arranged on the upper partition plate; and a lower mounting groove matched with the air outlet sleeve is formed in the lower partition plate.

As an improved mode, a plurality of cooling air holes are formed in the outer edge of the ionization sleeve and are arranged at intervals.

As an improvement mode, a plurality of cooling air holes are formed in the outer edge of the ionization sleeve and are spirally arranged along the outer edge of the ionization sleeve.

As a modification, the outer edge of the ionization sleeve is provided with cooling fins.

As an improvement mode, the upper partition plate and the lower partition plate are respectively provided with a positioning groove for positioning the insulating tape.

As a modification, the cooling gas is nitrogen.

By adopting the technical scheme, the beneficial effects of the utility model are that:

waterline disinfects and washs vertical forced air cooling ozone generator for all-in-one, include: the ionization device comprises a shell, wherein an ionization sleeve is vertically arranged in the shell and connected with a high-voltage electrode, a hollow cavity is arranged in the ionization sleeve, an upper partition plate and a lower partition plate are arranged in the hollow cavity, a plurality of vertical sleeves are arranged between the upper partition plate and the lower partition plate, and the sleeves and the ionization sleeve are integrally formed; an inner electrode is arranged in each sleeve, and the same sides of the inner electrodes are connected together through an insulating belt; the upper end of the ionization sleeve is provided with an air inlet sleeve, the lower end of the ionization sleeve is provided with an air outlet sleeve, and the air outlet sleeve and the air inlet sleeve both extend to the outside of the shell; one end of the sleeve extends into the air inlet sleeve, and the other end of the sleeve extends into the air outlet sleeve; the upper clapboard is provided with upper air holes which are positioned at the outer edge of the air inlet sleeve; the lower clapboard is provided with a lower air vent which is positioned at the outer edge of the air outlet sleeve; the lower end of the shell is provided with a cooling gas inlet pipe communicated with cooling gas, the upper end of the shell is provided with a cooling gas outlet pipe, oxygen enters from the gas inlet sleeve, and the sleeve and the ionization sleeve are integrally formed, and a plurality of inner electrodes adopt an outer electrode, so that the structure is simple and the installation is convenient; the surrounding area of the ionization sleeve is cooled through cooling gas, so that dead corners are avoided in cooling, and the cooling effect is good.

Because the flow equalizing plate is arranged in the air inlet sleeve and is provided with a plurality of flow equalizing holes, the high-purity oxygen is divided into a plurality of small air flows to enter the six sleeves respectively under the action of the flow equalizing plate, and the preparation efficiency of the ozone is further improved.

The upper baffle plate is provided with an upper mounting groove matched with the air inlet sleeve; be provided with the lower mounting groove with the cover looks adaptation of giving vent to anger on the baffle down, the installation is simple and convenient quick on the one hand, and on the other hand is convenient for go up the baffle and admit air between the cover and lower baffle and give vent to anger sealed between the cover.

Because the outer fringe of ionization cover is provided with a plurality of cooling gas pockets, a plurality of cooling gas pocket intervals are arranged, and cooling gas gives off around the ionization cover through the cooling gas pocket, and the cooling does not have the dead angle, guarantees the efficiency of cooling, sets up the cooling gas pocket simultaneously and can improve cooling gas's flow area, reinforcing flow rate, the heat of taking away in the improvement unit interval promotes the radiating effect.

Because the outer edge of the ionization sleeve is provided with the plurality of cooling air holes which are spirally arranged along the outer edge of the ionization sleeve, the cooling air is guided by the spirally arranged cooling air holes, and the spiral air flow is formed at the outer edge of the ionization sleeve, so that the contact area between the cooling air holes and the ionization sleeve is increased, and the cooling rate is improved.

Because the outer fringe of ionization cover is provided with cooling fin, the heat radiating area of increase ionization cover improves the radiating efficiency.

Because the cooling gas is nitrogen, the nitrogen is used for cooling the gas source, on one hand, the raw materials are easy to obtain, the price is low, on the other hand, the ionization sleeve can be dehumidified, and the service life of the ionization sleeve is prolonged.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive exercise.

Fig. 1 is a schematic structural view of the present invention;

FIG. 2 is an enlarged schematic view at A in FIG. 1;

FIG. 3 is a three-dimensional view of an ionization chamber according to one embodiment;

FIG. 4 is a three-dimensional view of the ionization chamber of the second embodiment;

FIG. 5 is a three-dimensional view of the ionization chamber of the third embodiment;

FIG. 6 is a schematic view of the installation of the insulating tape and the inner electrode;

wherein: 1-shell, 2-ionization sleeve, 3-high voltage electrode, 4-hollow cavity, 5-upper clapboard, 6-lower clapboard, 7-sleeve, 8-inner electrode, 9-insulating tape, 10-lantern ring, 11-air inlet sleeve, 12-air outlet sleeve, 13-upper air vent, 14-lower air vent, 15-cooling air inlet pipe, 16-cooling air outlet pipe, 17-flow equalizing plate, 18-flow equalizing hole, 19-upper mounting groove, 20-lower mounting groove, 21-expansion part, 22-cooling air vent, 23-cooling fin, 24-positioning groove and 25-sewage drain.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely 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 efforts belong to the protection scope of the present invention.

Example one

As shown in fig. 1, the vertical air-cooled ozone generator for the integrated machine for sterilizing and cleaning waterline comprises: the ionization device comprises a shell 1, wherein an ionization sleeve 2 which is vertically arranged is installed in the shell 1, the ionization sleeve 2 is connected with a high-voltage electrode 3, the high-voltage electrode 3 is connected with high-voltage electricity, a hollow cavity 4 is formed in the ionization sleeve 2, an upper partition plate 5 and a lower partition plate 6 are installed in the hollow cavity 4, and a plurality of vertical sleeves 7 are arranged between the upper partition plate 5 and the lower partition plate 6; an inner electrode 8 is arranged in each sleeve 7, and the same sides of the inner electrodes 8 are connected together through an insulating belt 9.

As shown in fig. 6, the insulating tape 9 of the present invention is preferably a polyvinyl chloride insulating tape, a sleeve ring 10 is disposed in the middle of the insulating tape 9, and the end of the inner electrode 8 is clamped into the sleeve ring 10.

The upper end of the ionization sleeve 2 is provided with an air inlet sleeve 11, the lower end of the ionization sleeve 2 is provided with an air outlet sleeve 12, and the air outlet sleeve 12 and the air inlet sleeve 11 both extend to the outside of the shell 1; one end of the sleeve 7 extends into the air inlet sleeve 11 and the other end of the sleeve 7 extends into the air outlet sleeve 12.

The upper clapboard 5 is provided with an upper air vent 13, and the upper air vent 13 is positioned at the outer edge of the air inlet sleeve 11; the lower clapboard 6 is provided with a lower air vent 14, and the lower air vent 14 is positioned at the outer edge of the air outlet sleeve 12.

The lower end of the shell 1 is provided with a cooling gas inlet pipe 15, and the upper end of the shell 1 is provided with a cooling gas outlet pipe 16.

As shown in fig. 1, a flow equalizing plate 17 is disposed in the air inlet sleeve 11, and a plurality of flow equalizing holes 18 are disposed on the flow equalizing plate 17.

As shown in fig. 2 and 3, the upper partition 5 is provided with an upper mounting groove 19 adapted to the air inlet sleeve 11; the lower clapboard 6 is provided with a lower mounting groove 20 matched with the air outlet sleeve 12.

The utility model discloses use the attached dust of 7 inner walls of sleeve after a period, influence ionization efficiency, consequently the lower extreme of gas outlet sleeve 12 is provided with the drain 25 of valve control, thereby injects the inside that the clear water washd sleeve 7 into in sleeve 7, utilizes drain 25 to discharge the clear water after the washing is accomplished.

The utility model discloses in, go up mounting groove 19 and all set up to the T-slot with lower mounting groove 20, the plastic is chooseed for use to the material of cover 11 and the cover 12 of giving vent to anger of admitting air, and the adaptation end setting of cover 11 and last mounting groove 19 of admitting air expands major part 21, will expand major part 21 and fill in mounting groove 19, be convenient for on the one hand sealed, and on the other hand installation is simple and convenient quick.

The installation principle of the air outlet sleeve 12 and the lower installation groove 20 is the same as that of the air inlet sleeve 11 and the upper installation groove 19, and the description is omitted here.

As shown in fig. 3, the outer fringe of ionization cover 2 is provided with a plurality of cooling gas holes 22, and a plurality of cooling gas holes 22 interval is arranged, through the cooling gas hole 22 that the interval set up, back in cooling gas lets in ionization cover 2, gives off around ionization cover 2 through cooling gas hole 22, and the cooling does not have the dead angle, guarantees the efficiency of cooling, sets up cooling gas hole 22 simultaneously and can improve the flow area of cooling gas, reinforcing flow rate, the heat of taking away in the improvement unit interval, promotes the radiating effect.

And the upper partition plate 5 and the lower partition plate 6 are respectively provided with a positioning groove 24 for positioning the insulating tape 9.

Example two

As shown in fig. 4, the present embodiment is different from the first embodiment in that: a plurality of cooling air holes 22 are arranged on the outer edge of the ionization sleeve 2, and the cooling air holes 22 are spirally arranged along the outer edge of the ionization sleeve 2.

EXAMPLE III

As shown in fig. 1, the vertical air-cooled ozone generator for the integrated machine for sterilizing and cleaning waterline comprises: the ionization device comprises a shell 1, wherein an ionization sleeve 2 which is vertically arranged is installed in the shell 1, the ionization sleeve 2 is connected with a high-voltage electrode 3, the high-voltage electrode 3 is connected with high-voltage electricity, a hollow cavity 4 is formed in the ionization sleeve 2, an upper partition plate 5 and a lower partition plate 6 are installed in the hollow cavity 4, and a plurality of vertical sleeves 7 are arranged between the upper partition plate 5 and the lower partition plate 6; an inner electrode 8 is arranged in each sleeve 7, and the same sides of the inner electrodes 8 are connected together through an insulating belt 9.

As shown in fig. 6, the insulating tape 9 of the present invention is preferably a polyvinyl chloride insulating tape, a sleeve ring 10 is disposed in the middle of the insulating tape 9, and the end of the inner electrode 8 is clamped into the sleeve ring 10.

The upper end of the ionization sleeve 2 is provided with an air inlet sleeve 11, the lower end of the ionization sleeve 2 is provided with an air outlet sleeve 12, and the air outlet sleeve 12 and the air inlet sleeve 11 both extend to the outside of the shell 1; one end of the sleeve 7 extends into the air inlet sleeve 11 and the other end of the sleeve 7 extends into the air outlet sleeve 12.

The upper clapboard 5 is provided with an upper air vent 13, and the upper air vent 13 is positioned at the outer edge of the air inlet sleeve 11; the lower clapboard 6 is provided with a lower air vent 14, and the lower air vent 14 is positioned at the outer edge of the air outlet sleeve 12.

The lower end of the shell 1 is provided with a cooling gas inlet pipe 15, and the upper end of the shell 1 is provided with a cooling gas outlet pipe 16.

As shown in fig. 1, a flow equalizing plate 17 is disposed in the air inlet sleeve 11, and a plurality of flow equalizing holes 18 are disposed on the flow equalizing plate 17.

As shown in fig. 2 and 3, the upper partition 5 is provided with an upper mounting groove 19 adapted to the air inlet sleeve 11; the lower clapboard 6 is provided with a lower mounting groove 20 matched with the air outlet sleeve 12.

The utility model discloses use the attached dust of 7 inner walls of sleeve after a period, influence ionization efficiency, consequently the lower extreme of gas outlet sleeve 12 is provided with the drain 25 of valve control, thereby injects the inside that the clear water washd sleeve 7 into in sleeve 7, utilizes drain 25 to discharge the clear water after the washing is accomplished.

The utility model discloses in, go up mounting groove 19 and all set up to the T-slot with lower mounting groove 20, the plastic is chooseed for use to the material of cover 11 and the cover 12 of giving vent to anger of admitting air, and the adaptation end setting of cover 11 and last mounting groove 19 of admitting air expands major part 21, will expand major part 21 and fill in mounting groove 19, be convenient for on the one hand sealed, and on the other hand installation is simple and convenient quick.

The installation principle of the air outlet sleeve 12 and the lower installation groove 20 is the same as that of the air inlet sleeve 11 and the upper installation groove 19, and the description is omitted here.

As shown in fig. 5, the upper partition 5 and the lower partition 6 are each provided with a positioning groove 24 for positioning the insulating tape 9.

The outer edge of the ionization sleeve 2 is provided with cooling fins 23, so that the heat dissipation area is increased, and the heat dissipation efficiency is improved.

The utility model discloses when using, because the density of oxygen is bigger than the air, consequently with the air inlet setting the utility model discloses an upper portion, oxygen gets into by the air inlet cover 11 on upper portion, and in a plurality of minute air currents got into six sleeves 7 respectively with high-purity oxygen through the effect of flow equalizing plate 17, because sleeve 7 and 2 integrated into one piece of ionization cover, high-tension electrode 3 is connected to ionization cover 2, and high-tension electrode 3 meets with the high tension electricity, and when consequently oxygen got into sleeve 7, under sleeve 7 and inner electrode 8's ionization, partial oxygen generated ozone and flowed out from giving vent to anger cover 12. When ionization preparation ozone, lower the temperature through cooling gas to ionization cover 2, for reducing the utility model discloses a cooling cost, the cooling gas head is preferably the nitrogen gas of low price as the cooling source, because the density of nitrogen gas is little than the air, nitrogen gas can rise in letting in the air, based on this principle, cooling gas intake pipe 15 sets up the lower part at the casing, cooling gas is got into by cooling gas intake pipe 15, and get into in the cavity 4 through bleeder vent 14 down, along with continuous letting in, cooling gas is by last bleeder vent 13 outflow cavity 4, and discharge from cooling gas outlet duct 16, thereby take away the heat that ionization in-process electrode gived off.

Because air inlet sleeve 11 and last baffle 5 are sealing connection, go out air sleeve 12 and baffle 6 sealing connection down, in the sleeve one end stretched into air inlet sleeve 11, in the other end stretched into air outlet sleeve 12, consequently oxygen and cooling gas formed two noninterference spaces, prevented to press from both sides in the cooling gas in the ozone that generates, improved ozone's preparation concentration.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. Waterline disinfects and washs vertical forced air cooling ozone generator for all-in-one, its characterized in that includes:

the ionization device comprises a shell, wherein an ionization sleeve which is vertically arranged is arranged in the shell, the ionization sleeve is connected with a high-voltage electrode, a hollow cavity is arranged in the ionization sleeve, an upper partition plate and a lower partition plate are arranged in the hollow cavity, a plurality of vertical sleeves are arranged between the upper partition plate and the lower partition plate, and the sleeves and the ionization sleeve are integrally formed; an inner electrode is arranged in each sleeve, and the same sides of a plurality of inner electrodes are connected together through an insulating belt;

the upper end of the ionization sleeve is provided with an air inlet sleeve, the lower end of the ionization sleeve is provided with an air outlet sleeve, and the air outlet sleeve and the air inlet sleeve both extend to the outside of the shell; one end of the sleeve extends into the air inlet sleeve, and the other end of the sleeve extends into the air outlet sleeve;

the upper clapboard is provided with upper air holes which are positioned at the outer edge of the air inlet sleeve; the lower clapboard is provided with a lower air vent which is positioned at the outer edge of the air outlet sleeve;

the lower end of the shell is provided with a cooling gas inlet pipe communicated with cooling gas, and the upper end of the shell is provided with a cooling gas outlet pipe.

2. The vertical air-cooled ozone generator for the integrated machine for sterilizing and cleaning the waterline as claimed in claim 1, wherein a flow equalizing plate is arranged in the air inlet sleeve, and a plurality of flow equalizing holes are arranged on the flow equalizing plate.

3. The vertical air-cooled ozone generator for the integrated waterline sterilization and cleaning machine as claimed in claim 1, wherein the upper partition plate is provided with an upper mounting groove adapted to the air inlet sleeve; and a lower mounting groove matched with the air outlet sleeve is formed in the lower partition plate.

4. The vertical air-cooled ozone generator for the integrated machine for sterilizing and cleaning the waterline as claimed in claim 1, wherein a plurality of cooling air holes are arranged at the outer edge of the ionization sleeve, and the plurality of cooling air holes are arranged at intervals.

5. The vertical air-cooled ozone generator for the integrated machine for sterilizing and cleaning the waterline as claimed in claim 1, wherein a plurality of cooling air holes are arranged on the outer edge of the ionization sleeve, and the plurality of cooling air holes are spirally arranged along the outer edge of the ionization sleeve.

6. The vertical air-cooled ozone generator for the integrated machine for sterilizing and cleaning the waterline as claimed in claim 1, wherein the outer edge of the ionization sleeve is provided with cooling fins.

7. The vertical air-cooled ozone generator for the integrated machine for sterilizing and cleaning the waterline as claimed in claim 1, wherein the upper partition plate and the lower partition plate are both provided with positioning grooves for positioning the insulating tape.

8. The vertical air-cooled ozone generator for the integrated waterline sterilization and cleaning machine as claimed in claim 1, wherein said cooling gas is nitrogen.

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