JP4874182B2 - Vacuum cleaner - Google Patents

Description

  The present invention relates to a vacuum cleaner having a function of performing deodorization and sterilization in a vacuum cleaner and keeping the interior of the vacuum cleaner clean, and in particular, a vacuum cleaner having improved deodorization efficiency and sterilization efficiency by utilizing ozone. It is about.

  In recent years, from the viewpoint of hygiene, a vacuum cleaner is required to keep the inside of the cleaner clean. In general, after a vacuum cleaner is used a plurality of times, waste such as dust accumulated in a dust collection unit (paper pack) is often discarded. Accordingly, dust is accumulated in the dust collecting portion for a long period of time. Therefore, the odor component and various germs contained in the trash are propagated inside the vacuum cleaner, and the hygiene in the vacuum cleaner is impaired. In addition, when the vacuum cleaner is activated, the odor components and germs inside the vacuum cleaner are discharged into the room together with the exhaust flow, which causes discomfort to the user.

In order to reduce this, a vacuum cleaner is proposed that is equipped with technologies such as deodorizing function and disinfecting function by providing ozone generating means in the vacuum cleaner and generating ozone by simple operation. (For example, refer to Patent Document 1). Ozone (O ₃ ) is very unstable and has a characteristic of giving one of oxygen atoms to another substance and trying to become a stable oxygen molecule (O ₂ ). That is, ozone has a strong oxidizing power. The electric vacuum cleaner described in Patent Document 1 uses the oxidizing power of ozone to deodorize and sterilize the inside of the vacuum cleaner.

Japanese Patent Laid-Open No. 7-124077 (page 3, FIG. 1)

  The vacuum cleaner described in Patent Document 1 aims at a deodorizing effect by reacting ozone in air. In this case, in order to obtain a deodorizing effect that can be sensed by the user's nose, it is necessary to generate ozone at a high concentration and for a long time. High-concentration ozone significantly reduces the strength of the components of the vacuum cleaner due to its strong oxidizing power. Moreover, ozone itself has a peculiar odor, and when ozone leaks outside a cleaner, it will give a user discomfort. In such a vacuum cleaner, the amount of ozone generated inside the ozone cleaner must be suppressed. If it does so, sufficient deodorizing effect by ozone will no longer be acquired.

  The present invention has been made in order to solve the above-described problems. An electric cleaning that can obtain a sufficient deodorizing effect with a small amount of ozone and can reduce the user's discomfort due to the odor of ozone itself. The purpose is to provide a machine.

The vacuum cleaner according to the present invention separates air sucked in together with the air in the swirl chamber by a suction power unit, a ventilation path that conducts air sucked by the suction power part, and the air that is disposed in the ventilation path. A centrifugal separation means for collecting the separated dust in the dust collection section; an ozone generation section that is disposed on the windward side of the dust collection section and generates ozone; and an inlet of the air in the centrifugal separation means And an odor adsorbing part that adsorbs an odor component generated from dust accumulated in the dust collection unit and an odor component of ozone generated from the ozone generation unit. It is characterized by that.

  According to the vacuum cleaner according to the present invention, by using the ozone generating unit and the odor adsorbing unit in combination, the odor adsorbing unit absorbs and concentrates unpleasant odor components generated from the dust accumulated in the dust collecting unit. , Generate ozone from the ozone generator, increase the contact probability of this ozone and unpleasant odor components, prevent the accumulation of unpleasant odor components inside the vacuum cleaner even with a small amount of ozone, this unpleasant odor component and ozone odor component It is possible to reduce the occurrence of an unpleasant exhaust odor and leakage to the outside.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
Embodiment 1 FIG.
FIG. 1 is a perspective view showing a schematic configuration of a vacuum cleaner 100 according to Embodiment 1 of the present invention. A schematic configuration of the electric vacuum cleaner 100 will be described with reference to FIG. In addition, in the following drawings including FIG. 1, the relationship of the size of each component may be different from the actual one. In the vacuum cleaner 100, the suction port body 24 that sucks dust such as dust is connected to the vacuum cleaner exterior 1 via the hose 21, and the sucked dust is collected in a paper pack or the like (see FIG. 6). The air after collecting in the part 4 and collecting the dust is exhausted from the vacuum cleaner exterior 1.

  As shown in FIG. 1, the vacuum cleaner 100 includes a vacuum cleaner exterior 1 and a hose unit 20 that is detachably attached to a suction port connection portion 2 provided on the front surface of the vacuum cleaner exterior 1. . The hose unit 20 is connected to the hose 21 connected to the suction port connection portion 2, the handle portion 22 provided on the distal end side, the pipe 23 connected to the distal end side of the handle portion 22, and the distal end of the pipe 23. And a suction port body 24. Air containing dust such as dust sucked from the suction port body 24 passes through the pipe 23 and the hose 21 and is sucked into the vacuum cleaner exterior 1. The handle portion 22 is provided with a power supply operation portion 25. The power operation unit 25 is provided with a power switch and the like (not shown).

  FIG. 2 is a schematic diagram for explaining an example of the internal configuration of the vacuum cleaner exterior 1. FIG. 3 is a plan view showing a state in which the vacuum cleaner exterior 1 of the electric vacuum cleaner 100 is viewed from above. Based on FIG.2 and FIG.3, an example of the internal structure of the cleaner exterior 1 is demonstrated. In addition, in FIG. 3, the flow of the air in the cleaner exterior 1 is represented by the arrow. Two openings are formed in the vacuum cleaner exterior 1 so that the opening surface is substantially perpendicular to the ground. Of these openings, the suction port connection portion 2 is formed on the front side, and the exhaust port 31 is formed on the back side.

  The suction port connecting portion 2 serves as an air inlet. A hose unit 20 is connected to the suction port connecting portion 2 using a fitting or the like, and air is sucked through the hose unit 20 and enters the interior of the vacuum cleaner exterior 1. The exhaust port 31 serves as an air outlet inside the vacuum cleaner exterior 1. That is, the exhaust port 31 is sucked into the vacuum cleaner exterior 1 together with dust and discharges air after the dust is removed to the outside of the vacuum cleaner exterior 1. In addition, the formation position of the suction port connection part 2 and the exhaust port 31 is not specifically limited, What is necessary is just to determine a formation position according to the shape of the cleaner exterior 1. FIG.

  An ozone generator 6 is attached to the vacuum cleaner exterior 1 by an ozone generator holder 3 (see FIG. 2). The ozone generation unit 6 is located inside the ozone generation unit holder 3 and is installed so as to have a negative pressure without allowing the main flow of the suction air in the ventilation path 32 to flow when the suction power unit 5 is driven. It shall be. The ozone generating unit holder 3 has an opening surface that is substantially perpendicular to the opening surface of the suction port connection unit 2. The generation of ozone from the ozone generator 6 will be described with reference to FIG.

  A dust collection unit 4 and a suction power unit 5 are mounted inside the vacuum cleaner exterior 1. The dust collection part 4 has two openings, the opening surface of one opening is positioned substantially perpendicular to the ozone generator holder 3, and the opening surface of the other opening is positioned opposite the inner surface. A paper pack or the like can be accommodated, and is configured to be detachable from the vacuum cleaner exterior 1. The suction power unit 5 is composed of a motor or the like, and serves as a power source for sucking air into the cleaner exterior 1. The suction power unit 5 is installed on the side of the opening located on the opposite side of the opening that is positioned substantially perpendicular to the ozone generation unit holder 3 of the dust collection unit 4.

  A ventilation path 32 for air (suction air) sucked from the suction port connection portion 2 is formed inside the vacuum cleaner exterior 1. This ventilation path 32 is formed by arranging the suction port connecting part 2, the ozone generating part holding body 3, and the dust collecting part 4 in order from the windward side to the leeward side. It is a flowing air path. The ventilation path 32 may be provided with a branch path in addition to the ventilation path 32, but it is desirable that the ventilation path 32 is configured so that the influence on the suction force of the suction power unit 5 is slight and the pressure loss is not increased. In other words, a pressure loss body such as a metal mesh may be provided in the ventilation path 32, or the suction air may be circulated. Also, the suction power may be negative when the suction power unit 5 is activated, or the suction air may be difficult to ventilate. Therefore, it is desirable that the influence of the ventilation path 32 on the suction force of the suction power unit 5 be small.

  The vacuum cleaner exterior 1 is provided with an openable / closable lid (not shown) that can be closed to cover the ozone generator 3, the dust collector 4, and the suction power unit 5. . Moreover, when providing a metal mesh, if the metal mesh is subjected to at least one of antibacterial processing, fungicidal processing, deodorizing processing, and the like, the sanitary surface inside the vacuum cleaner exterior 1 can be further improved. Moreover, you may make it provide the filter etc. for collecting the fine dust (fine dust) which passes a metal mesh.

  FIG. 4 is an enlarged front view of the ozone generator 6 and the ozone generator holder 3 as seen from the front side. Based on FIG. 4, the ozone generation part 6 and the ozone generation part holding body 3 are demonstrated in detail. As described above, the ozone generator 6 is stored in a form housed in the ozone generator holder 3. And the ozone generation part 6 is fixed by the projection part 3a etc. which are provided in the ozone generation part holding body 3. FIG. Ozone generated from the ozone generator 6 conducts through the ozone inflow path 7 formed inside the ozone generator holder 3 and diffuses from the ozone vent 8 to the ventilation path 32.

  The ozone vent 8 is formed so that the ozone generator holding body 3 and the ventilation path 32 communicate with each other. Further, the ozone vent 8 is formed so that the opening surface has a predetermined angle with respect to the ground (horizontal plane) and faces toward the dust collecting unit 4. That is, the ozone generator holding body 3 is formed so as to communicate with the dust collector 4 via the dust collector suction port 12 (see FIG. 6). By adopting such a configuration, it is possible to prevent a pressure loss body from being present between the ozone vent 8 and the dust collecting unit 4, and the diffusion of ozone between the ozone generating unit 6 and the dust collecting unit 4 is hindered. There is nothing. At this time, it is desirable that the ozone vent 8 is formed by two or more through holes or provided with a mesh. In addition, you may comprise the ozone inflow path | route 7 using a tube etc.

  FIG. 5 is a schematic configuration diagram showing a schematic configuration of the ozone generator 6. A mechanism for generating ozone from the ozone generator 6 will be described with reference to FIG. The ozone generator 6 is composed of a needle-like projection electrode 9 and a ground electrode 10, and a high voltage is applied between the needle-like projection electrode 9 and the ground electrode 10 to generate a corona discharge. Oxygen is converted into ozone by energy to generate ozone. Since the ozone generator 6 is applied with a high voltage or generates heat, the constituent material of the ozone generator holder 3 to which the ozone generator 6 is attached preferably has flame retardancy.

  Here, the case where the ozone generator 6 generates ozone by the electric discharge method has been described as an example. However, the present invention is not limited to this, and any method that can generate ozone may be used. For example, an ultraviolet ray method or a creeping discharge method may be adopted for the ozone generation unit 6, and it may be determined according to the capacity or manufacturing cost of the vacuum cleaner 100. Further, the shape of the ozone generator 6 is not particularly limited, and may be determined according to the shape and size of the ozone generator holder 3, the method of generating the adopted ozone, and the like.

  FIG. 6 is an enlarged side view showing the dust collecting portion 4. Based on FIG. 6, the dust collection part 4 is demonstrated in detail. As shown in FIG. 6, the dust collecting unit 4 includes an opening / closing door 11, a dust collecting unit suction port 12, a paper pack 13, a filter 14, and a dust collecting unit exhaust port 15, and air flows in order. ing. The opening and closing door 11 opens and closes to communicate or block the inside and outside of the dust collection unit 4. When the dust collection part 4 is removed, the open / close door 11 is in a closed state and suppresses leakage of dust accumulated in the dust collection part 4 and ozone diffused inside. On the other hand, when the dust collection unit 4 is attached, that is, when connected to the vacuum cleaner 100, the open / close door 11 is opened, and the dust collection unit 4 and the ozone generation unit are connected via the dust collection unit suction port 12. The holding body 3 is connected.

  The dust collection unit suction port 12 serves as an inlet for air flowing into the dust collection unit 4 and is opened or closed by the open / close door 11. The paper pack 13 is detachable inside the dust collecting unit 4 and accumulates sucked dust. The filter 14 is a non-woven fabric to which a deodorizing material such as activated carbon or zeolite is attached, a deodorizing filter having a shape such as a corrugate or a honeycomb, or a filtering material having a high collection efficiency, such as a polymer filtering material or HEPA (High Efficiency Particulate). Air) A filter medium, ULPA (Ultra Low Penetration Air) filter medium, etc. is composed of a pleated filter that is folded into a pleat shape, and is arranged on the downstream side of the paper pack 13 so as to pass through the paper pack 13 Is to collect. The dust collection unit exhaust port 15 is connected to the suction power unit side and serves as an outlet for air flowing out from the dust collection unit 4.

  A portion where the filter 14 and the dust collecting unit exhaust port 15 are held may be used as a lid so that the dust collecting unit 4 can be opened and closed according to the attachment and detachment of the dust collecting unit 4 from the vacuum cleaner 100. It should be noted that the paper pack 13 can be exchanged by opening this lid. When the vacuum cleaner 100 is activated, the suction air sucked into the vacuum cleaner 100 sequentially passes through the dust collector suction port 12, the paper pack 13, the filter 14, and the dust collector exhaust port 15 for suction. It is guided to the power unit 5.

  FIG. 7 is an enlarged longitudinal sectional view showing the paper pack 13 as viewed from the side. A specific configuration of the paper pack 13 will be described with reference to FIG. As shown in FIG. 7, the paper pack 13 includes an outer paper 16 and an odor adsorbing portion 17. The exterior paper 16 constitutes the outline of the paper pack 13. The odor adsorbing unit 17 adsorbs the odor generated from the debris of garbage accumulated therein and the odor of ozone, and preferably constitutes the innermost layer of the paper pack 13. Moreover, it is desirable that the odor adsorbing portion 17 includes at least one of activated carbon or manganese oxide (catalyst).

  One or more layers may be further formed between the outer paper 16 and the odor adsorbing portion 17, and the paper pack 13 may have a three-layer structure. Even in such a case, it is desirable that the odor adsorbing portion 17 constitutes the innermost layer of the paper pack 13. Further, the paper pack 13 is not limited to the shape shown in FIG. Further, the exterior paper 16 and the odor adsorbing portion 17 may be configured as one body or may be configured as separate bodies. In the case where the exterior paper 16 and the odor adsorbing unit are configured separately, the odor adsorbing unit 17 may not be provided in the innermost layer of the paper pack 13, and the filter 14 may replace the odor adsorbing unit 17. . However, in this case, it is necessary to provide the filter 14 with a deodorizing function.

  Next, the operation of the vacuum cleaner 100 will be described. In the vacuum cleaner 100, when the suction power unit 5 is activated, the suction air passes through the hose unit 20, the suction port connection unit 2, the ozone generation unit holder 3, and the dust collecting unit 4 in order, and dust contained in the suction air is collected. It is blocked by the paper pack 13 contained in the dust collecting unit 4, separated from the suction air, and accumulated in the paper pack 13. An unpleasant odor is generated from the dust accumulated in the paper pack 13 in the dust collecting section 4. In a state where the suction power unit 5 is not in operation, a concentration gradient is generated in the internal space of the dust collection unit 4 and the other vacuum cleaner 100 due to unpleasant odor components, so that the concentration balance is achieved. An unpleasant odor component stays inside.

  The unpleasant odor staying inside the vacuum cleaner 100 becomes an exhaust odor when the suction power unit 5 is restarted, and is released to the outside of the vacuum cleaner 100, causing unpleasant feeling to the user. On the other hand, in the vacuum cleaner 100 according to the first embodiment, the ozone generating unit 6 is provided between the suction port connecting unit 2 and the dust collecting unit 4, and the odor adsorbing unit 17 is disposed at a position in direct contact with dust. A paper pack 13 is provided. In a state where the suction power unit 5 is not in operation, the odor adsorbing unit 17 that is in direct contact with the trash adsorbs unpleasant odor components staying inside the vacuum cleaner 100 and reduces the unpleasant odor. In addition to this, by generating ozone from the ozone generating unit 6, the unpleasant odor component is oxidized, and the unpleasant odor component adsorbed on the odor adsorbing unit 17 is also oxidized to be a different component.

  By doing so, a part of the unpleasant odor component is re-released as an odorless component, and a part is adsorbed to an adsorption site different from the component before the change, so that the adsorption power of the unpleasant odor component of the odor adsorbing portion 17 can be recovered. (See FIG. 14). Since the unpleasant odor component is sufficiently adsorbed on the odor adsorbing portion 17 and the unpleasant odor component is in a very high density state, the probability of contact between the unpleasant odor component and ozone is greatly increased. Oxidation proceeds significantly more than occurs in air. Thereby, the amount of ozone can at least sufficiently reduce unpleasant odor components, and the adsorption performance of the odor adsorption unit 17 can be maintained longer. Therefore, sufficient exhaust unpleasant odor removal performance can be obtained even with low concentration and short-time ozone generation. Moreover, it is not necessary to generate a large amount of ozone, and the discomfort given to the user by the ozone odor can be reduced.

  Next, an optimal operation example of the ozone generator 6 of the electric vacuum cleaner 100 according to the first embodiment will be described. It is desirable to generate ozone when the vacuum cleaner 100 is stopped. That is, when ozone is generated when the vacuum cleaner 100 is operating, the vicinity of the ozone generating unit 6 and the ozone inflow path 7 become negative pressure, obstructing the generation of ozone, and the generated ozone is uncomfortable. This is because it is discharged to the outside of the vacuum cleaner 100 before reacting with the odor, and a sufficient unpleasant odor reduction effect cannot be obtained. Therefore, it is desirable that ozone is generated between the moment when the user finishes cleaning and the power of the vacuum cleaner 100 is turned off until the power cord is unplugged, so that the user does not feel bothered.

  Note that if the user removes the hose 21 or the dust collecting unit 4 in a state where ozone is being generated, the ozone that may be felt by the user's nose may leak. The vacuum cleaner 100 may be provided with an ozone generation control mechanism configured by a microcomputer or the like that stops ozone generation when the lid (not shown) is opened so as to remove the dust collecting unit 4. desirable. In addition, as shown in FIG. 5, the ozone generation unit 6 generates ozone by corona discharge that has a stable ozone generation amount and can generate a sufficiently high ozone concentration even in a small and simple shape. It is suitable to use a vessel.

FIG. 8 is a graph showing the amount of ozone generated with respect to the applied current of the ozone generator 6. Based on FIG. 8, the relationship between the applied current in the ozone generator 6 and the amount of ozone generated will be described. In FIG. 8, the vertical axis represents the amount of ozone generated (mg / m ³ ), and the horizontal axis represents the applied current (−μA). In addition, in this FIG. 8, the graph of the ozone generation amount with respect to the applied electric current about the ozone generation part 6 of the electric discharge system which generates ozone by the corona discharge shown in FIG. 5 is represented.

  As shown in FIG. 8, the ozone generation amount tends to increase with the applied current. That is, the ozone generation amount when the applied current is 100 is larger than the ozone generation amount when the applied current is 40. Therefore, the ozone concentration can be estimated from the applied current value, and the ozone generation amount can be adjusted relatively easily by controlling the applied voltage or applied current. Further, when corona discharge is used, ions (negative ions and positive ions) are also generated at the same time, so that a synergistic effect between the ions and ozone can be expected.

  FIG. 9 is a graph showing changes in ozone attenuation rate with respect to ozone generation time. Based on FIG. 9, the relationship between the ozone generation time in the ozone generator 6 and the ozone attenuation rate will be described. In FIG. 9, the vertical axis represents the ozone decay rate (%), and the horizontal axis represents the ozone generation time (hr). When corona discharge is adopted for the ozone generating section 6, the acicular projection electrode 9 is worn with the use time, and the amount of generated ozone is reduced. FIG. 9 shows that the ozone decay rate exceeds 50 when the ozone generation time exceeds 500 hours.

  Therefore, as shown in FIG. 9, when corona discharge is employ | adopted for the ozone generation part 6, it turns out that ozone attenuates with operation time. Therefore, the ozone generator 6 is included in an ozone generator holder 3 formed as a separate component from the vacuum cleaner exterior 1 so that it can be attached and detached relatively easily, and the cleaner exterior 1 and the ozone generator holder 3 are included. It is desirable to fix with a fixing member (projection 3a in FIG. 4) such as a claw or a screw. By doing in this way, the exchange operation and maintenance operation | work of the ozone generation part 6 by a user can be performed easily, and the usability of the vacuum cleaner 100 can be improved.

  FIG. 10 is a graph showing the VI characteristics of the ozone generator 6 mounted on the vacuum cleaner 100. Based on FIG. 10, the VI characteristic of the ozone generation part 6 is demonstrated. In FIG. 10, the vertical axis represents the current value (−μA), and the horizontal axis represents the voltage value (−kV). As shown in FIG. 10, when the voltage applied to the ozone generator 6 is not −3 [kV] or higher, no discharge occurs and no current flows, so no ozone is generated. On the other hand, when the applied voltage exceeds −10 [kV], the discharge becomes unstable and the electrode wears heavily, and the stability of the ozone generation amount is impaired.

  Therefore, when the ozone generator 6 employing such corona discharge is mounted, the applied voltage is required to be controlled between −3 [kV] and −10 [kV]. In addition, if a large amount of dust adheres to the ozone generation unit 6, the discharge is hindered, and the ozone generation amount decreases. Therefore, it is desirable that the ventilation path 32 in the portion where the ozone ventilation hole 8 is formed has a higher direction of the dust collection part 4. Therefore, the ozone vent 8 is formed such that its opening surface is inclined (beveled) at a predetermined angle with respect to the ground (horizontal plane), and the opening surface faces the direction of the dust collecting portion 4. . Thereby, the inflow of suction air is not hindered, and the diffusion of ozone is easily directed toward the dust collecting unit 4. Further, if the ozone vent 8 is formed by two or more through-holes or a mesh is provided, dust flowing into the ozone generator 6 can be further prevented.

  Next, the deodorizing performance of the electric vacuum cleaner 100 according to Embodiment 1 will be described. FIG. 11 is a graph showing changes over time in TVOC (total volatile organic compound) removal performance. Based on FIG. 11, the difference in the deodorizing performance due to the presence or absence of the odor adsorbing unit 17 of the vacuum cleaner 100 is determined based on the ozone only configuration, the odor adsorbing unit 17 only, and the ozone + odor adsorbing unit 17 configuration. The change over time of the TVOC removal performance in this case will be described. In FIG. 11, the vertical axis indicates the TVOC remaining rate (%), and the horizontal axis indicates the elapsed time (s). Here, the amount of ozone generated is assumed to be constant, and the same components are used for the odor adsorbing portion 17.

  In the case of the configuration of only ozone (the line (A) shown in the figure), since the oxidation occurs only in the air, the TVOC removal performance does not appear remarkably. In addition, in the configuration having only the odor adsorbing portion 17 (the line (b) shown in the figure), the adsorption performance is limited, and the TVOC removal performance cannot be obtained after a certain amount of adsorption reaction. On the other hand, in the case of the configuration in which the ozone + odor adsorbing portion 17 is combined (line (c) shown in the figure), the adsorption performance of the odor adsorbing portion 17 can be recovered and the performance can be maintained for a long time. . At this time, if ozone decomposition such as activated carbon or manganese oxide is promoted and a substance having high odor adsorption performance is attached to the odor adsorbing portion 17, the leakage of ozone to the outside of the vacuum cleaner 100 can be expected.

  FIG. 12 is a graph showing the results obtained by sampling the unpleasant odor of the vacuum cleaner 100 and measuring it by GC / MS (gas chromatography / mass spectrometry). Based on FIG. 12, the exhaust unpleasant odor of the vacuum cleaner 100 will be described by comparing the case where ozone is generated for 0.3 PPm × 6 minutes with the odor adsorbing portion 17 and the case where no ozone is generated. To do. FIG. 12A shows the case where ozone is not generated, and FIG. 12B shows the case where ozone is generated. In both cases, the vertical axis indicates the exhaust unpleasant odor component (%), and the horizontal axis indicates the elapsed time. (Time) is shown. Here, the case where analysis is mainly performed on a VOC (volatile organic compound) component is shown as an example.

  As shown in FIG. 12 (a) and FIG. 12 (b), compared with the case where ozone is not generated by generating ozone, mainly acetaldehyde (arrow (D) shown in the figure), EMK (ethyl methyl ketone). ) (The arrow (E) shown in the figure) was confirmed to be attenuated. The removal rate of acetaldehyde at this time was 43 [%], and the removal rate of EMK was 25 [%]. In addition, the number described in FIG. 12A and FIG. 12B represents elapsed time.

  FIG. 13 is a graph showing the change with time of the removal rate of acetaldehyde. Based on FIG. 13, the change with time of the removal rate of acetaldehyde when ozone is generated and reacted in air with respect to 10 [ppm] of acetaldehyde will be described. In FIG. 13, the vertical axis represents the acetaldehyde removal rate (%), and the horizontal axis represents the ozone concentration (ppb). FIG. 13 also shows the acetaldehyde removal rate after 15 minutes (line (f)), the acetaldehyde removal rate after 30 minutes (line (g)), and the acetaldehyde removal rate after 45 minutes (line (h)). Is shown.

  Even if ozone concentration 5 [ppm] is generated for 45 minutes, the removal rate of acetaldehyde is only about 23 [%] when ozone is reacted in the air without providing the odor adsorbing portion 17. Even if ozone concentration 5 [ppm] is generated for 30 minutes, the removal rate of acetaldehyde is only about 18 [%] when ozone is reacted in the air without providing the odor adsorbing portion 17. Furthermore, even if ozone concentration 5 [ppm] is generated for 15 minutes, the acetaldehyde removal rate when ozone is reacted in the air without providing the odor adsorbing portion 17 is only about 9 [%]. That is, in any case, as shown in FIG. 12, the acetaldehyde removal rate of 43 [%] in the state where the odor adsorbing portion 17 is present is not reached. From this, it can be seen that the odor adsorbing portion 17 works effectively.

  FIG. 14 is an explanatory diagram for explaining the effect of oxidation by ozone on the odor adsorbing portion 17. Based on FIG. 14, the effect of oxidation by ozone on the odor adsorbing portion 17 will be described. In FIG. 14, (A) represents the odor component A, (I) represents the odor component B, and (U) represents ozone. First, the odor component A generated from the dust is trapped (adsorbed and held) by the odor adsorbing unit 17. On the other hand, by generating ozone, the odor component A and ozone react with high probability, and the odor component A trapped on the odor adsorbing portion 17 is oxidized and changed to the odor component B. .

  Since the odor component B has different properties, the odor component B is once separated from the odor adsorbing portion 17 and trapped in a portion (different adsorption site) different from the portion adsorbed before, or remains in the air as it is. If it does so, it will become possible to trap the new odor component A in the part where the odor component A was trapped before being oxidized. Therefore, through such a cycle, the odor adsorbing unit 17 is recovered. At this time, of course, ozone is also oxidatively reacting with the odor component in the air, and appears as a synergistic effect by the combined use of ozone and the odor adsorbing portion 17.

  As described above, the vacuum cleaner 100 according to Embodiment 1 uses the ozone generating unit 6 and the odor adsorbing unit 17 in combination to odorize unpleasant odor components generated from the dust accumulated in the dust collecting unit 4. While adsorbing and concentrating in the adsorbing unit 17, ozone is generated from the ozone generating unit 6 to increase the contact probability between the ozone and the unpleasant odor component, and to prevent the unpleasant odor component from staying in the vacuum cleaner 100 even with a small amount of ozone. In addition, the unpleasant odor component and the ozone odor component are reduced from leaking to the outside as an unpleasant odor of exhaust.

Embodiment 2. FIG.
FIG. 15 is a plan view showing a state in which the vacuum cleaner exterior 1 of the electric vacuum cleaner 200 according to Embodiment 2 of the present invention is viewed from above. An example of the internal configuration of the vacuum cleaner exterior 1 will be described with reference to FIG. In the second embodiment, the differences from the first embodiment will be mainly described, and the same parts as those in the first embodiment are denoted by the same reference numerals and the description thereof will be omitted. Moreover, in FIG. 15, the flow of the air in the cleaner exterior 1 is represented by an arrow. An example of the electric vacuum cleaner 200 shown in FIG. 15 employs a cyclone separation structure (centrifugation means 40) that generates a swirling airflow and separates air and dust using centrifugal force.

  In the vacuum cleaner 100 according to the first embodiment, the case where the odor adsorbing portion 17 is provided in the innermost layer of the paper pack 13 is shown as an example. However, in the vacuum cleaner 200 according to the second embodiment, the paper pack 13 is Since the cyclone separation structure is not provided, the case where the odor adsorbing portion 17a is separately provided is shown as an example. The odor adsorbing portion 17 a has the same function as the odor adsorbing portion 17 and is provided between the suction port connecting portion 2 and the dust collecting portion 4. FIG. 15 shows an example in which the odor adsorbing portion 17 a is provided in the swirl chamber 41. Further, the odor adsorbing portion 17a may be configured with a filter or the like.

  The centrifuge 40 is composed of a swirl chamber 41 that separates dust and air and a dust collection unit 4. In the swirl chamber 41, a swirl flow is generated. The dust sucked into the swirl chamber 41 together with the air swirls along the inner peripheral side wall surface of the swirl chamber 41 by the centrifugal force of swirl flow, flows out of the swirl chamber 41, and collects the dust. 4 is accumulated. In addition, a metal mesh 18 is provided at the outlet of the suction air flowing out from the dust collecting unit 4 so that dust does not flow out from the dust collecting unit 4. A filter 19 for collecting fine dust that has passed through the metal mesh 18 is provided in the ventilation path 32 between the dust collection unit 4 and the suction power unit 5. The filter 19 may be configured by using a filter medium having a high collection efficiency, such as a polymer filter medium, a HEPA filter medium, a ULPA filter medium, or the like.

  In the electric vacuum cleaner 200, the positional relationship between the ozone generating unit holder 3 and the odor adsorbing unit 17a is not particularly limited, but the odor adsorbing unit 17a is located at a position where the main flow of the suction air does not flow, that is, the ventilation path. It is assumed that 32 is installed on the inner wall surface side. Moreover, in the vacuum cleaner 200, the ventilation path 32 from the suction port connection part 2 to the dust collection part 4 is not provided with a pressure loss body such as a filter. The generated ozone easily diffuses to the odor adsorbing part 17a and the dust collecting part 4.

  Next, the operation of the electric vacuum cleaner 200 will be described. In the vacuum cleaner 200, when the suction power unit 5 is started, the suction air is sequentially conducted through the hose unit 20, the suction port connection unit 2, the ozone generation unit holder 3, the swirl chamber 41, the dust collection unit 4, and the filter 19. The dust contained in the suction air is centrifuged with the suction air in the swirl chamber 41 and accumulated in the dust collecting section 4. Thus, since the vacuum cleaner 200 has the cyclone separation structure, it is not necessary to replace the paper pack 13, the pressure loss is reduced, and the suction force is improved.

  In the vacuum cleaner 100, the odor adsorbing portion 17 is included in the paper pack 13, but in the electric vacuum cleaner 200, the odor adsorbing portion 17a is located closer to the ozone generating portion 6 (in FIG. 15, the ozone generating portion 6). Therefore, the unpleasant odor can be reduced with a smaller amount of ozone. The odor adsorbing unit 17a may be provided at a position closer to the ozone generating unit 6 and the installation position is not particularly limited, but is a position closer to the ozone generating unit 6 and does not cause pressure loss of the ventilation path 32. It is desirable to provide it.

  FIG. 16 is a graph showing changes in the suction air volume with respect to the rotation speed of the suction power unit 5. Based on FIG. 16, the change of the suction | attraction air volume with respect to the rotation speed of the attraction | suction power part 5 by the difference in the installation position of the odor adsorption | suction part 17a is demonstrated. In FIG. 16, the suction air volume (m3 / min) is shown on the vertical axis, and the rotation speed (rpm) of the suction power unit 5 is shown on the horizontal axis. As shown in FIG. 16, the increase in the air volume with respect to the rotational speed when the odor adsorbing portion 17 a is installed on the inlet facing the dust collecting portion 4 where the main flow of the suction air in the ventilation path 32 does not vent (solid line (re) shown in the figure). On the other hand, it can be confirmed that the increase in the air volume (broken line (nu) in the figure) with respect to the rotational speed when the odor adsorbing portion 17a is installed at the position where the main flow of the suction air in the ventilation path 32 is ventilated is suppressed.

  In particular, as the air volume increases, the effect due to the difference in installation position of the odor adsorbing portion 17a appears greatly. Since the reduction in the suction air amount directly leads to the reduction in the dust collection efficiency, it can be seen that it is effective to install the odor adsorbing portion 17a avoiding the position where the main flow of the suction air in the ventilation path 32 is vented. Further, the unpleasant exhaust odor is emitted from the dust accumulated in the dust collecting unit 4 when the electric vacuum cleaner 200 is stopped, and it is not always necessary to remove the odor component during the operation of the electric vacuum cleaner 200. Therefore, it is desirable to install the odor adsorbing portion 17a while avoiding the position where the main flow of the suction air in the ventilation path 32 is vented.

  FIG. 17 is a graph showing temporal changes in the acetaldehyde concentration. Referring to FIG. 17, when the odor generating source is sucked into the vacuum cleaner 200 without installing the odor adsorbing portion 17 a, the dust collecting portion 4 / suction port connecting portion 2, the upstream side of the filter 19, and the filter 19. The time-dependent change of the acetaldehyde concentration on the downstream side will be described. In FIG. 17, the vertical axis represents the acetaldehyde concentration, and the horizontal axis represents time (min). In addition, the line (le) indicates the temporal change in the acetaldehyde concentration in the dust collection unit 4 and the suction port connection part 2, and the line (o) indicates the change in the acetaldehyde concentration in the upstream side of the filter 19 over time. ) Shows temporal changes in the acetaldehyde concentration on the downstream side of the filter 19.

  As the odor generating source shown in FIG. 17, it is assumed that a fibrous paper in which an acetaldehyde solution is absorbed is used. In the dust collection part 4 and the suction port connection part 2 (line (le)), since there is nothing that interferes with the suction air, the acetaldehyde concentration changes with time, and acetaldehyde is released first. A rapid increase in concentration occurs due to the rapid diffusion, and the concentration decreases rapidly. However, after that, the release becomes constant, and the concentration is stabilized when the diffusion is completed.

  On the other hand, on the upstream side of the filter 19 (line (W)), since the metal mesh 18 is provided, the metal mesh 18 hinders the initial concentration increase with respect to the dust collection part 4 and the suction port connection part 2. It can be confirmed that there is a tendency to decrease by half and the concentration after stabilization also decreases. Further, on the downstream side of the filter 19 (line (wa)), in addition to the metal mesh 18, it is blocked by the filter 19, so that almost no change in density can be confirmed, and stable at a low density. The tendency of being can be confirmed. From this, it can be seen that the shields acting as pressure loss bodies such as the metal mesh 18 and the filter 19 prevent the diffusion of the odor and affect the deodorization. Therefore, it is desirable to install the odor adsorbing portion 17a while avoiding the position where the main flow of the suction air in the ventilation path 32 is vented.

FIG. 18 is a graph showing changes in ozone concentration with respect to the distance from the ozone generator 6. Based on FIG. 18, changes in the ozone concentration with respect to the distance from the ozone generator 6 will be described. In FIG. 18, the vertical axis represents the ozone concentration (mg / m ³ ), and the horizontal axis represents the distance (mm) from the ozone generator 6. As can be seen from FIG. 18, the ozone concentration decreases as the distance from the ozone generator 6 increases. Therefore, the closer the distance between the ozone generating unit 6 and the odor adsorbing unit 17a, the more ozone can be brought into contact with the odor adsorbing unit 17a in a short time, and the unpleasant odor reducing effect is enhanced. For this reason, it is desirable that the positional relationship between the ozone generating unit 6 and the odor adsorbing unit 17a be closer.

  As described above, the vacuum cleaner 200 according to Embodiment 2 uses the ozone generator 6 and the odor adsorber 17a in combination to odorize unpleasant odor components generated from the dust accumulated in the dust collector 4. While adsorbing and concentrating in the adsorbing unit 17a, ozone is generated from the ozone generating unit 6 to increase the contact probability between the ozone and the unpleasant odor component, and to prevent the unpleasant odor component from staying in the vacuum cleaner 200 even with a small amount of ozone. In addition, the unpleasant odor component and the ozone odor component are reduced from leaking to the outside as an unpleasant odor of exhaust.

It is a perspective view which shows the general | schematic structure of the vacuum cleaner which concerns on Embodiment 1. FIG. It is the schematic for demonstrating an example of the internal structure of a cleaner exterior. It is a top view which shows the state which looked at the vacuum cleaner exterior of the vacuum cleaner from the upper surface. It is a front view which expands and shows the state which looked at the ozone generation part and the ozone generation part holding body from the front side. It is a schematic block diagram which shows schematic structure of an ozone generation part. It is a side view which expands and shows a dust collection part. It is a longitudinal cross-sectional view which expands and shows the state which looked at the paper pack from the side. It is a graph which shows the ozone generation amount with respect to the applied current of an ozone generation part. It is a graph which shows the change of the ozone attenuation rate with respect to ozone generation time. It is a graph which shows the VI characteristic of the ozone generation part mounted in a vacuum cleaner. It is a graph which shows a time-dependent change of TVOC removal performance. It is a graph which shows the result of having sampled the unpleasant odor of the vacuum cleaner, and having measured by GC / MS. It is a graph which shows the change with time of the removal rate of acetaldehyde. It is explanatory drawing for demonstrating the effect of the oxidation by ozone on an odor adsorption part. It is a top view which shows the state which looked at the vacuum cleaner exterior of the vacuum cleaner which concerns on Embodiment 2 from the upper surface. It is a graph which shows the change of the suction air volume with respect to the rotation speed of a suction power part. It is a graph which shows the time change of an acetaldehyde density | concentration. It is a graph which shows the change of the ozone concentration with respect to the distance from an ozone generation part.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 Vacuum cleaner exterior, 2 Suction port connection part, 3 Ozone generation part holding body, 3a Protrusion part, 4 Dust collection part, 5 Suction power part, 6 Ozone generation part, 7 Ozone inflow path, 8 Ozone vent, 9 Needle shape Projection electrode, 10 Ground electrode, 11 Opening / closing door, 12 Dust collection unit suction port, 13 Paper pack, 14 Filter, 15 Dust collection unit exhaust port, 16 Outer paper, 17 Odor adsorption unit, 17a Odor adsorption unit, 18 Metal mesh, DESCRIPTION OF SYMBOLS 19 Filter, 20 Hose unit, 21 Hose, 22 Handle part, 23 Pipe, 24 Suction port body, 25 Power supply operation part, 31 Exhaust port, 32 Ventilation path, 40 Centrifugation means, 41 Swirling chamber, 100 Vacuum cleaner, 200 Electric vacuum cleaner.

Claims (15)

A suction power unit;
A ventilation path for conducting air sucked in by the suction power unit;
Centrifugation means that is disposed in the ventilation path, separates the dust sucked together with the air from the air in a swirl chamber, and collects the separated dust in a dust collecting portion;
An ozone generating unit disposed on the windward side of the dust collecting unit and generating ozone;
An odor component generated from dust accumulated in the dust collection portion and an odor component of ozone generated from the ozone generation portion disposed between the air inlet and the dust collection portion in the centrifugal separator. And an odor adsorbing part for adsorbing odor. The odor adsorbing part is
The vacuum cleaner according to claim 1, comprising at least one of manganese oxide and activated carbon. The ozone generator is attached to an ozone generator holder that is installed outside the ventilation path,
In the ozone generation part holder,
An ozone inflow path for circulating ozone generated from the ozone generating unit;
The electric vacuum cleaner according to claim 1 or 2, wherein an ozone ventilation hole that connects the ozone inflow path and the ventilation path is formed. The electric vacuum cleaner according to claim 3, wherein the ozone generator holding body is made of a flame retardant material. The vacuum cleaner according to claim 3 or 4, wherein the ozone inflow path is configured by a tube. The vacuum cleaner according to any one of claims 3 to 5, wherein the ozone vent is configured by two or more through holes. The vacuum cleaner according to any one of claims 3 to 6, wherein the ozone vent is provided with a mesh. The ozone vent is
The vacuum cleaner according to any one of claims 3 to 7, wherein the opening surface has a predetermined angle with respect to a horizontal plane and faces the direction of the dust collecting portion. A hose unit that is detachably connected to the ventilation path is provided,
When the hose unit is removed,
The said ozone generation part is stopped. The vacuum cleaner in any one of Claims 1-8 characterized by the above-mentioned. The vacuum cleaner according to any one of claims 1 to 9, wherein an opening / closing door is provided at a connection portion with the ventilation path on the upstream side of the dust collection unit. A lid that can be opened and closed is provided above the dust collecting part.
When the lid is opened,
The said ozone generation part is stopped. The vacuum cleaner in any one of Claims 1-10 characterized by the above-mentioned. The ozone generator is
12. The electric vacuum cleaner according to claim 1, wherein an ozone generation method of any one of a corona discharge method, an ultraviolet ray method, and a creeping discharge method is employed. In the ozone generating unit that generates ozone by a corona discharge method,
The vacuum cleaner according to claim 12, wherein a voltage of -3 kV to -10 kV is applied to an electrode constituting the ozone generating unit. The vacuum cleaner according to claim 1, wherein ions are generated simultaneously with ozone from the ozone generation unit. The said ozone generation part is operated at the time of OFF of a vacuum cleaner. The vacuum cleaner in any one of Claims 1-14 characterized by the above-mentioned.

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