CN112978681A - Improved electric shock device for generating ozone - Google Patents

Abstract

The invention relates to the technical field of ozone generation devices, and provides an improved electric shock device for generating ozone, which comprises a shell, wherein the upper end of the shell is connected with an installation cover, an electrode connector is arranged on the installation cover, a cooling sleeve is arranged on the inner wall of the shell, electric shock equipment is arranged in the cooling sleeve, an ozone generation cavity is arranged between the electric shock equipment and the cooling sleeve, two gas pipes are inserted into the side wall of the shell, and the two gas pipes are respectively a first gas pipe positioned at the upper end of the side wall of the shell and a second gas pipe positioned on the bottom wall of the shell. The invention overcomes the defects of the prior art, has reasonable design and compact structure, solves the problems of low ozone generation efficiency, easy damage to the quartz tube and poor cooling effect of the traditional electric shock equipment, improves the ozone generation efficiency by adopting the spiral high-voltage electrode to replace the traditional electrode, is not easy to damage the quartz tube, prolongs the service life and has strong practicability.

Description

Improved electric shock device for generating ozone

Technical Field

The invention relates to the technical field of ozone generating devices, in particular to an improved electric shock device for generating ozone.

Background

Ozone is an allotrope of oxygen. A light blue gas with a fishy smell. Ozone has strong oxidizing property, is a stronger oxidant than oxygen, and can play a role in disinfection and sterilization.

The current ozone machines generate ozone by electric shock, and the traditional ozone machine electric shock equipment has the following problems:

1. the common electrode is in single-point contact with the conductive metal film, so that on one hand, an electric field formed on the conductive metal film is uneven, and therefore the generated ozone efficiency is not high, and on the other hand, due to the fact that the electrode is in single-point contact with the conductive metal film, abnormal electric arcs generated by poor contact after long-time use are prone to breakdown a quartz tube, and equipment damage is caused.

2. The traditional electric shock equipment is not ideal enough in cooling effect, and easily causes ozone to be actively decomposed into oxygen under the abnormal arc condition, so that the ozone generation effect is influenced.

3. The connector connected with the electrode is positioned in the quartz tube, the electrode connector is easy to age and damage after being used for a long time, and the electrode connector is positioned in the quartz tube, so that the electrode connector is inconvenient to replace and overhaul.

4. The lower end of the shell of the traditional electric shock equipment is connected through a sealant and a screw, so that ozone gas leakage is easy to occur, and the whole electric shock equipment is corroded and damaged.

To this end, we propose an improved electric stun device for generating ozone.

Disclosure of Invention

Technical problem to be solved

Aiming at the defects of the prior art, the invention provides an improved electric shock device for generating ozone, which overcomes the defects of the prior art, has reasonable design and compact structure, solves the problems of low ozone generation efficiency, easy damage to a quartz tube and poor cooling effect of the traditional electric shock equipment, improves the ozone generation efficiency by adopting a spiral high-voltage electrode to replace the traditional electrode, is not easy to damage the quartz tube, prolongs the service life and has strong practicability.

(II) technical scheme

In order to achieve the purpose, the invention is realized by the following technical scheme:

an improved electric shock device for generating ozone comprises a shell, wherein the upper end of the shell is connected with an installation cover, an electrode connector is arranged on the installation cover, a cooling sleeve is arranged on the inner wall of the shell, an electric shock device is arranged in the cooling sleeve, and an ozone generating cavity is arranged between the electric shock device and the cooling sleeve;

the side wall of the shell is spliced with two gas pipes, namely a first gas pipe positioned at the upper end of the side wall of the shell and a second gas pipe positioned on the bottom wall of the shell, and the other ends of the first gas pipe and the second gas pipe penetrate through the cooling sleeve and extend into the ozone generation cavity;

the electric shock equipment comprises a quartz tube, an upper sealing cover is connected to the upper end of the quartz tube in a sealing mode, a high-voltage electrode rod is inserted into the upper sealing cover in a plugging mode, the upper end of the high-voltage electrode rod penetrates through an installation cover and is connected with an electrode connector in an interconnected mode, the lower end of the high-voltage electrode rod extends to the inner bottom wall of the quartz tube, a spiral high-voltage electrode is connected to one section of the high-voltage electrode rod, which is located in the quartz tube, and the lower end of the quartz tube.

Furthermore, a connecting sheet is fixed on the electrode connecting head, one end of the connecting sheet is connected with a lead, and a rubber sheath corresponding to the connecting sheet is sleeved on the electrode connecting head.

Furthermore, the upper end of the side wall of the shell is connected with a fixing block corresponding to the mounting cover, and the fixing block is connected with the mounting cover.

Furthermore, it has two liquid pipes to peg graft on the lateral wall of shell, is the first liquid pipe that is located the shell lateral wall upper end and is located the second liquid pipe of shell lateral wall lower extreme respectively, and first liquid pipe and second liquid pipe all extend to in the cooling jacket.

Furthermore, the spiral high-voltage electrode is connected to the inner wall of the conductive metal film, and the conductive metal film is connected to the inner wall of the quartz tube.

Furthermore, the lower end of the lower sealing cover is connected with a rubber block.

Furthermore, an insulating sheath is connected to the electrode connecting head.

Furthermore, the high-voltage electrode rod is made of stainless steel.

Further, the shell is a sleeve with an opening at the upper end.

(III) advantageous effects

Embodiments of the present invention provide an improved electric stun device for generating ozone. The method has the following beneficial effects:

1. the efficiency of ozone generation can be improved. The spiral high-voltage electrode is connected to the inner wall of the conductive metal film through a wire, the conductive metal film is connected to the inner wall of the quartz tube and is in line connection with the conductive metal film through the spiral high-voltage electrode, so that an even electric field can be formed on the conductive metal film, the even electric field can shock oxygen in the air, ozone can be generated evenly, and the production capacity of the ozone is improved.

2. Preventing breakdown of the quartz tube. Because the spiral high-voltage electrode is in line contact with the conductive metal film, an even electric field can be generated, abnormal electric arcs are prevented from being generated, then the quartz tube is prevented from being broken down, and the service life of electric shock equipment is prolonged.

3. Can reach the effect of cooling, prevent on the one hand that the ozone high temperature from decomposing automatically, improve the generation efficiency of ozone then, on the other hand can protect electric shock equipment, improves electric shock equipment's life. Be provided with cooling jacket on the inner wall of shell, the coolant liquid has been held in the cooling jacket, and it has two liquid pipes to peg graft on the lateral wall of shell, and one is the feed liquor pipe, and another is the drain pipe, through feed liquor pipe and external water source through connection, can drive the coolant liquid among the cooling jacket and flow, improves the cooling effect to ozone, improves ozone generation effect then, reduces the temperature of electric shock equipment simultaneously, improves the life of electric shock equipment.

4. The electrode connector is convenient to replace and overhaul. Meanwhile, the connecting piece is connected to the electrode connecting head through a screw, the electrode connecting head is located outside the electric shock equipment, and when the electrode connecting head or the connecting piece is damaged after long-term use, the electrode connecting head is convenient to replace or overhaul, and the replacement and overhaul efficiency is improved.

5. Reduce the leakage of ozone and prevent the damage to the shell. Because the shell only has an upper end opening, and the ozone generating cavity is positioned inside the cooling sleeve, the leakage of ozone can be reduced.

Drawings

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic cross-sectional view of the structure of the present invention;

FIG. 3 is a schematic sectional view of the electric stun apparatus of the present invention;

fig. 4 is an enlarged schematic view of the structure B in fig. 2.

In the figure: the ozone generator comprises a shell 1, a first gas pipe 1.1, a second gas pipe 1.2, a fixing block 1.3, an installation cover 2, an electrode connector 3, a lead 3.1, a rubber sheath 3.1.1, a connecting sheet 3.2, a cooling sleeve 4, a first liquid pipe 4.1, a second liquid pipe 4.2, an electric shock device 5, a quartz pipe 5.1, an upper sealing cover 5.2, a high-voltage electrode rod 5.3, a conductive metal film 5.4, a lower sealing cover 5.5, a rubber block 5.6, a spiral high-voltage electrode 5.7 and an ozone generation cavity a.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, 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 some, but not all, embodiments of the present invention. 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.

Example 1:

referring to the accompanying drawings 1-4, an improved electric shock device for generating ozone comprises a shell 1, wherein the shell 1 is a sleeve with an opening at the upper end, the sleeve can prevent generated ozone from overflowing from the lower end of the shell 1, the shell 1 is corroded and damaged, the upper end of the shell 1 is connected with an installation cover 2, the upper end of an ozone generation cavity a is sealed through the installation cover 2, gas overflow is prevented, an electrode connector 3 is installed on the installation cover 2, a cooling sleeve 4 is connected to the inner wall of the shell 1, cooling liquid is contained in the cooling sleeve 4, the temperature of electric shock gas can be reduced, the temperature is prevented from being too high, the ozone generation effect is influenced, ozone can be automatically decomposed into oxygen under the condition of too high temperature, the ozone generation effect is required to be improved through the temperature reduction, meanwhile, the temperature of an electric shock device 5 is reduced, and the service life of the electric shock.

In this embodiment, as shown in fig. 2, an electric shock device 5 is disposed in the cooling sleeve 4, and an ozone generation cavity a is disposed between the electric shock device 5 and the cooling sleeve 4, so that the sealing effect of the ozone generation cavity a can be improved, and the ozone is prevented from overflowing from the lower end of the ozone generation cavity a. Two gas pipes are inserted into the side wall of the shell 1, namely a first gas pipe 1.1 positioned at the upper end of the side wall of the shell 1 and a second gas pipe 1.2 positioned on the bottom wall of the shell 1, the other ends of the first gas pipe 1.1 and the second gas pipe 1.2 penetrate through the cooling sleeve 4 and extend into the ozone generation cavity a, one of the first gas pipe 1.1 or the second gas pipe 1.2 is an air inlet, the other one is an ozone outlet, and air is conveyed into the ozone generation cavity a through the air inlet;

in this embodiment, as shown in fig. 3, the electric shock device 5 includes a quartz tube 5.1, an upper sealing cap 5.2 is hermetically connected to an upper end of the quartz tube 5.1, a high voltage electrode rod 5.3 is inserted into the upper sealing cap 5.2, an upper end of the high voltage electrode rod 5.3 passes through the mounting cap 2 and is connected to the electrode connector 3, a lower end of the high voltage electrode rod 5.3 extends to an inner bottom wall of the quartz tube 5.1, a section of the high voltage electrode rod 5.3 located inside the quartz tube 5.1 is connected to a spiral high voltage electrode 5.7, the spiral high voltage electrode 5.7 is of a spiral structure, an upper end and a lower end of the spiral high voltage electrode 5.7 are connected to the high voltage electrode rod 5.3 through point contact, the spiral high voltage electrode 5.7 is connected to an inner wall of the conductive metal film 5.4 through a wire, and the conductive metal film 5.4 is connected to the conductive metal film 5.4 through the spiral high voltage electrode 5.7, so as to form a uniform electric field on the conductive metal film 5., even electric field can shock to the oxygen in the air to can be even produce ozone, improve the production of ozone, simultaneously because be line contact between spiral high voltage electrode 5.7 and the conductive metal film 5.4, can prevent that unusual electric arc from puncturing quartz capsule 5.1, improve the life of electric shock equipment 5, the lower extreme of quartz capsule 5.1 is connected with down sealed lid 5.5.

The specific working principle is as follows: air is conveyed to the ozone generation cavity a through an air inlet, at the moment, a power supply is switched on, the electric quantity is conveyed to the high-voltage electrode rod 5.3 through the wire 3.1 and the electrode connector 3 is conveyed to the high-voltage electrode rod 5.3, the electric quantity is conveyed to the spiral high-voltage electrode rod 5.7 through the high-voltage electrode rod 5.3 and then conveyed to the conductive metal film 5.4 through the spiral high-voltage electrode 5.7, so that an even electric field is formed on the conductive metal film 5.4, the electric field can shock the oxygen in the air, the oxygen is changed into ozone, the produced ozone can be discharged from an ozone outlet, the ozone production process is completed, meanwhile, the cooling liquid in the cooling sleeve 4 can cool the ozone, the abnormal ozone arc is prevented from being actively decomposed into the oxygen, the ozone generation effect is influenced, meanwhile, the temperature of the electric shock equipment 5 is reduced, and the.

In this embodiment, as shown in fig. 4, there is connection piece 3.2 through the fix with screw on the electrode connector 3, the one end of connection piece 3.2 is connected with wire 3.1, and cup joint 3.1.1 with the corresponding rubber sheath of connection piece 3.2 on the electrode connector, rubber sheath 3.1.1 is insulating material, can prevent to electrocute, the effect of protection is improved, simultaneously because connection piece 3.2 passes through screwed connection on electrode connector 3, and electrode connector 3 is located outside electric shock equipment 5, after electrode connector 3 or connection piece 3.2 use the damage for a long time, conveniently change or overhaul, improve the efficiency of changing the maintenance.

In this embodiment, as shown in fig. 1, 2 and 4, the upper end of the side wall of the housing 1 is connected with a fixing block 1.3 corresponding to the mounting cover 2, and the fixing block 1.3 and the mounting cover 2 are connected with each other through screws, so that the connection effect between the housing 1 and the mounting cover 2 is improved, and the upper end of the ozone generating cavity a is sealed.

In this embodiment, as shown in fig. 1 and 2, two liquid pipes are inserted into the side wall of the housing 1, which are respectively a first liquid pipe 4.1 located at the upper end of the side wall of the housing 1 and a second liquid pipe 4.2 located at the lower end of the side wall of the housing 1, and the first liquid pipe 4.1 and the second liquid pipe 4.2 both extend into the cooling sleeve 4, one of the first liquid pipe 4.1 and the second liquid pipe 4.2 is a liquid inlet pipe, and the other is a liquid outlet pipe, and is connected with an external water source through the liquid inlet pipe, so as to drive the cooling liquid in the cooling sleeve 4 to flow, thereby improving the cooling effect on ozone, further improving the ozone generation effect, simultaneously reducing the temperature of the electric shock device 5, and prolonging the service life of the electric shock.

In this embodiment, as shown in fig. 2 and 3, the lower end of the lower sealing cover 5.5 is connected with the rubber block 5.6, the electric shock device 5 is connected with the cooling sleeve 4 through the rubber block 5.6, and the rubber block 5.6 is made of a soft material, so that the buffering effect can be achieved, a certain protection effect is achieved on the quartz tube 5.1, the space of the ozone generation cavity a can be improved, the contact effect of oxygen in the air and an electric field is improved, and the generation efficiency of ozone is improved.

In this embodiment, as shown in fig. 1 and 4, the electrode connector 3 is connected to an insulating sheath, and the insulating sheath in this embodiment is made of ceramic, so as to achieve an insulating effect.

In this embodiment, the high voltage electrode rod 5.3 is made of stainless steel, which reduces oxidation and improves service life.

Example 2:

the difference with embodiment 1 lies in that spiral high voltage electrode 5.7 is two arc circles that are parallel to each other, and arc circle one end is connected on high voltage electrode pole 5.3 through electrically conductive connecting rod, and the outer wall of arc circle and stainless steel film 5.4 line contact, and two arc circles are connected respectively at the upper and lower both ends of stainless steel film 5.4, and with the up end parallel arrangement of stainless steel film 5.4.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

The above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (9)

1. The utility model provides an improved generation electric shock device for producing ozone, includes the shell, and the upper end of shell is connected with the installation lid, and the installation is covered and is provided with electrode connector, its characterized in that: a cooling sleeve is arranged on the inner wall of the shell, an electric shock device is arranged in the cooling sleeve, and an ozone generating cavity is arranged between the electric shock device and the cooling sleeve;

the side wall of the shell is spliced with two gas pipes, namely a first gas pipe positioned at the upper end of the side wall of the shell and a second gas pipe positioned on the bottom wall of the shell, and the other ends of the first gas pipe and the second gas pipe penetrate through the cooling sleeve and extend into the ozone generation cavity;

the electric shock equipment comprises a quartz tube, an upper sealing cover is connected to the upper end of the quartz tube in a sealing mode, a high-voltage electrode rod is inserted into the upper sealing cover in a plugging mode, the upper end of the high-voltage electrode rod penetrates through an installation cover and is connected with an electrode connector in an interconnected mode, the lower end of the high-voltage electrode rod extends to the inner bottom wall of the quartz tube, a spiral high-voltage electrode is connected to one section of the high-voltage electrode rod, which is located in the quartz tube, and the lower end of the quartz tube.

2. The improved electric stun device for generating ozone as recited in claim, wherein: the electrode connector is fixed with a connecting sheet, one end of the connecting sheet is connected with a lead, and the electrode connector is sleeved with a rubber sheath corresponding to the connecting sheet.

3. An improved electric stun device for generating ozone as recited in claim 1 wherein: the lateral wall upper end of shell is connected with the fixed block corresponding with the installation lid, and fixed block and installation lid interconnect.

4. An improved electric stun device for generating ozone as recited in claim 1 wherein: the lateral wall of shell is gone up to peg graft and is had two liquid pipes, is the first liquid pipe that is located shell lateral wall upper end and is located the second liquid pipe of shell lateral wall lower extreme respectively, and first liquid pipe and second liquid pipe all extend to in the cooling jacket.

5. An improved electric stun device for generating ozone as recited in claim 1 wherein: the spiral high-voltage electrode is connected to the inner wall of the conductive metal film, and the conductive metal film is connected to the inner wall of the quartz tube.

6. An improved electric stun device for generating ozone as recited in claim 1 wherein: the lower end of the lower sealing cover is connected with a rubber block.

7. An improved electric stun device for generating ozone as recited in claim 1 wherein: and the electrode connecting head is connected with an insulating sheath.

8. An improved electric stun device for generating ozone as recited in claim 1 wherein: the high-voltage electrode rod is made of stainless steel.

9. An improved electric stun device for generating ozone as recited in claim 1 wherein: the shell is a sleeve with an opening at the upper end.

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