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CN-224233886-U - Plasma generating module, plasma generating device and air conditioner

CN224233886UCN 224233886 UCN224233886 UCN 224233886UCN-224233886-U

Abstract

The utility model relates to the technical field of air treatment, in particular to a plasma generation module, a plasma generation device and an air conditioner, and aims to solve the problems that equipment for sterilizing and removing peculiar smell in the prior art is low in sterilizing and removing peculiar smell efficiency, large in occupied space, high in cost and the like. For this purpose, the plasma generating module of the utility model comprises at least one plasma generating assembly, the plasma generating assembly comprises a first electrode, a second electrode and an insulating medium layer, the first electrode and the second electrode are respectively arranged on two sides of the insulating medium layer, the first electrode and the second electrode are respectively attached to each other through the insulating medium layer, and when the plasma generating assembly is electrified and operated, the electrical property of the first electrode is opposite to that of the second electrode. According to the utility model, through the arrangement of the first electrode, the second electrode and the insulating medium layer, a relatively uniform electric field can be formed, plasma is generated by ionization, and the air is simultaneously sterilized and deodorized, so that a relatively good effect can be obtained.

Inventors

  • GUO JIAXING
  • CHANG JIANG
  • PAN JINXIAO
  • WU HONGJIN
  • LAO CHUNFENG
  • ZHANG PENG
  • ZHANG ZHAN
  • MA CHENG
  • LIU XIANGYU
  • SHANG QINGHAO
  • LIU KUO

Assignees

  • 青岛海尔空调器有限总公司
  • 海尔智家股份有限公司

Dates

Publication Date
20260512
Application Date
20250411

Claims (10)

  1. 1. The utility model provides a plasma generation module, its characterized in that, plasma generation module (11) include at least one plasma generation subassembly (111), plasma generation subassembly (111) include first electrode (1111), second electrode (1112) and insulating medium layer (1113), first electrode (1111) with second electrode (1112) set up respectively in insulating medium layer (1113) both sides, first electrode (1111) with second electrode (1112) respectively insulating medium layer (1113) both sides laminating each other, when plasma generation subassembly (111) circular telegram, first electrode (1111) with second electrode (1112) electric property is opposite.
  2. 2. The plasma generation module according to claim 1, wherein a mounting position is formed at a side portion of the insulating medium layer (1113), and the first electrode (1111) and/or the second electrode (1112) are respectively embedded in the corresponding mounting position.
  3. 3. The plasma generation module of claim 1, wherein a size of one of the first electrode (1111) and the second electrode (1112) is smaller than a size of the other.
  4. 4. The plasma generation module according to claim 1, wherein the first electrode (1111) is provided with a first through hole (11111), the first through hole (11111) penetrating the first electrode (1111) in a thickness direction of the first electrode (1111), and/or The second electrode (1112) is provided with a second through hole (11121), and the second through hole (11121) penetrates through the second electrode (1112) along the thickness direction of the second electrode (1112).
  5. 5. The plasma generation module according to claim 1, wherein the plasma generation module (11) further comprises a base (12), the plasma generation assembly (111) is clamped to the base (12), and the plasma generation module (11) is disposed on a target component through the base (12).
  6. 6. The plasma generation module according to claim 5, characterized in that the plasma generation module (11) further comprises a housing (13), the housing (13) is arranged on the base (12), a ventilation structure (131) is arranged on the housing (13), and the housing (13) is covered on the outer side of the plasma generation module (11).
  7. 7. The plasma generation module of claim 6, wherein the plasma generation module (11) comprises a plurality of plasma generation assemblies (111), at least some of the plasma generation assemblies (111) being spaced apart along the length of the base (12), at least a portion of the ventilation structure (131) being aligned with a gap between two adjacent plasma generation assemblies (111).
  8. 8. The plasma generation module according to any of claims 1 to 7, wherein the plasma generation assembly (111) comprises two insulating medium layers (1113), one of the first electrode (1111) and the second electrode (1112) being arranged between the two insulating medium layers (1113), the other of the first electrode (1111) and the second electrode (1112) being arranged at the sides of the two insulating medium layers (1113) facing away from each other, respectively.
  9. 9. A plasma-generating device, characterized in that the plasma-generating device (1) comprises at least one plasma-generating module (11) as claimed in any of the preceding claims 1 to 8.
  10. 10. An air conditioner characterized in that it is equipped with a plasma generation module (11) according to any one of the preceding claims 1 to 8, or The air conditioner is provided with a plasma generating device (1) as claimed in claim 9.

Description

Plasma generating module, plasma generating device and air conditioner Technical Field The utility model relates to the technical field of air treatment, and particularly provides a plasma generation module, a plasma generation device and an air conditioner. Background An air conditioner generally exchanges heat between indoor air and an indoor heat exchanger, thereby achieving the purpose of adjusting the temperature of an indoor space. After the service time is long, a large amount of bacteria, viruses and particulate matters can be accumulated in the air conditioner, and the indoor air can carry the bacteria, viruses and particulate matters in the air conditioner to an indoor space when exchanging heat with the indoor heat exchanger, so that the air quality of the indoor space is reduced, and the health of people is seriously endangered. In addition, as the doors and windows are usually closed in the running process of the air conditioner, peculiar smell can be generated indoors, smoke smell, bathroom peculiar smell and the like can be generated when people move indoors, and families with pets can generate corresponding peculiar smell which seriously affect comfort level. Therefore, the cost is high because people often dispose a sterilizing device on the air conditioner to perform sterilizing treatment and dispose an odor removing device to perform odor removing treatment. In the prior art, an ozone device and a silver ion device can only perform sterilization treatment generally, an activated carbon filter screen and a photocatalyst device can only perform odor removal treatment generally, and meanwhile, the cost of configuring the two devices is high, and more space is occupied. In addition, ozone is a harmful substance, and the ozone needs to be subjected to harmless treatment while being sterilized, so that the ozone equipment has a complex structure and high overall cost. Silver ion sterilization has poor initiative, and air can be sterilized only through a silver ion device. The activated carbon filter screen has poor deodorizing efficiency, more activated carbon filter screens are generally required to be configured to improve deodorizing effect, the occupied space is large, wind resistance can be generated, the activated carbon filter screen needs to be replaced regularly, and secondary pollution is caused by overflow after adsorption saturation. The photocatalyst device is usually used by matching a light source with a catalyst net, the occupied space is large, wind resistance is generated, and the cost is high. The negative ion device can sterilize and remove peculiar smell simultaneously, but negative ions are easily adsorbed and neutralized by particles (such as dust and the like) due to negative charges, the service life is short, the negative ions are consumed in a short-distance range, the negative ions are difficult to reach a position far away from the negative ions, and the sterilizing and deodorizing effects are limited. Accordingly, there is a need in the art for a new solution to the above-mentioned problems. Disclosure of utility model The utility model aims to solve the technical problems that the sterilizing and deodorizing equipment in the prior art has low sterilizing and deodorizing efficiency, large occupied space, high cost and the like. In a first aspect, the present utility model provides a plasma generating module, the plasma generating module (11) includes at least one plasma generating component (111), the plasma generating component (111) includes a first electrode (1111), a second electrode (1112) and an insulating medium layer (1113), the first electrode (1111) and the second electrode (1112) are respectively disposed on two sides of the insulating medium layer (1113), the first electrode (1111) and the second electrode (1112) are respectively attached to two sides of the insulating medium layer (1113), and when the plasma generating component (111) is powered on, the first electrode (1111) and the second electrode (1112) are opposite in electrical property. In a preferred embodiment of the plasma generating module, an installation site is formed on a side portion of the insulating medium layer (1113), and the first electrode (1111) and/or the second electrode (1112) are/is embedded in the installation site. In a preferred embodiment of the above-described plasma generating module, one of the first electrode (1111) and the second electrode (1112) has a smaller size than the other. In a preferred embodiment of the plasma generating module, the first electrode (1111) is provided with a first through hole (11111), and the first through hole (11111) penetrates the first electrode (1111) along the thickness direction of the first electrode (1111), and/or The second electrode (1112) is provided with a second through hole (11121), and the second through hole (11121) penetrates through the second electrode (1112) along the thickness direction of the second electrode (1112).