JP2008055331A - Filter for air cleaner and air cleaner using it - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a filter for air cleaners is capable of capturing dust effectively and ensuring an air flow and allows a long-period use. <P>SOLUTION: The first filter passage 22 having the first filter medium 20 and the second filter passage 23 having the second filter medium 21 are arranged in parallel. The second filter medium 21 is arranged obliquely with respect to the first filter medium 20 so that dust D captured by the second filter medium 21 is guided to the first filter medium 20 through an air flow toward the first filter medium 22. The second filter medium 21 has a conical shape, and the first medium 20 has a cylindrical shape so as to surround the periphery of the second filter medium 21. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an air cleaner filter for purifying air sucked into a vehicle engine, for example, and an air cleaner provided with the filter.

  Conventionally, as this type of air cleaner, for example, a configuration as disclosed in Patent Document 1 and Patent Document 2 has been proposed. In these conventional configurations, a honeycomb type air filter is accommodated in a casing having an air inlet and an air outlet on both sides. This air filter is formed in a cylindrical shape as a whole by winding a laminated material composed of a flat filter medium sheet and a corrugated filter medium sheet in a spiral shape. With this configuration, a plurality of air passages are defined by the wave-shaped filter medium between the flat filter media of the laminated material arranged in a spiral shape.

Of the air passages, of the air passages arranged at intervals, the end portion on the side corresponding to the air outlet of the casing is sealed, and the remaining air passages are sealed with the air inlet of the casing. And the end on the corresponding side are sealed. The air flowing in from the air inlet of the casing is introduced into one air passage from one end of the air filter, filtered through a flat filter medium sheet or a corrugated filter medium sheet, and then passed through the other air passage. It is led out from the other end side of the air filter and flows out from the air outlet of the casing.
Japanese Utility Model Publication No. 2-129231 Japanese Utility Model Publication No. 2-127766

  However, in these air cleaners, when dust is accumulated and clogging occurs, the air flow resistance of the air filter increases, so that the air flow rate decreases and the engine output decreases. Therefore, in such a case, it is necessary to clean or replace the air filter, which takes time for maintenance and is not economical. Moreover, this type of filter is often unevenly clogged, and in such a case, the air flow rate of the entire air filter is reduced even if there is a portion that is not clogged. Requires cleaning and replacement.

  In order to cope with such a problem, for example, in the air cleaner described in Patent Document 1, a three-dimensional prefilter made of a continuous foamed sponge or the like is disposed close to the center of the front surface of the air filter. According to this configuration, air is preliminarily filtered through the prefilter at the central portion of the air filter corresponding to the air inlet of the casing, and then introduced into the air filter and filtered again. Thus, it is possible to suppress local clogging at the central portion of the air filter.

  However, in the configuration described in Patent Document 1, dust easily accumulates in the prefilter. When dust accumulates in this way, the ventilation resistance of the prefilter increases, the air flow rate to the subsequent air filter decreases, and the filtration efficiency of the air filter decreases, so it is necessary to replace the prefilter frequently. There is.

  On the other hand, in the air cleaner described in Patent Document 2, a dust collecting member including a conical shunt and a plurality of grids extending radially from the outer peripheral edge of the shunt is disposed at the front center of the air filter. . According to this structure, air flowing in from the air intake port of the housing is guided toward the outer periphery of the air filter by the shunt of the dust collecting member, and large dust such as leaves and paper pieces contained in the air is captured by the lattice. Is done. Therefore, the possibility that large dust does not reach the air filter and the opening end surface on the inlet side of the air filter can be suppressed can be suppressed.

  However, in the configuration described in Patent Document 2, since a flow divider that inhibits the flow of air is disposed close to the center of the front surface of the air filter, the air flow rate to the subsequent air filter is reduced, and the air filter There is a possibility that the filtration efficiency of the filter is lowered. In addition, since the center of the front surface of the air filter is blocked by a shunt, even if the air filter is locally clogged, the airflow resistance increases significantly, requiring replacement of the air filter, etc. There was a problem of becoming.

  The present invention has been made paying attention to such problems existing in the prior art. An object of the present invention is to provide an air cleaner filter that can effectively filter dust and secure an air flow rate over a long period of time.

  In order to achieve the above object, an invention relating to an air cleaner filter includes a first filtration channel provided with a first filter material and a second filter channel provided with a second filter material, which are adjacent to each other, The second filter medium is arranged in an inclined state toward the first filter medium so that the dust trapped on the second filter medium is guided and guided to the first filter medium side.

  Therefore, in this invention, when air flows along the 1st and 2nd filtration flow path, the dust contained in air is filtered and captured by the 1st and 2nd filtration material. In this case, the dust trapped on the second filter medium is guided and guided to the first filter medium side by the flow of air to the first filter flow path side, and is accumulated in the first filter medium. For this reason, in the 2nd filtration flow path side provided with the 2nd filtration material, an air flow rate can always be ensured and the possibility that ventilation resistance may rise can be controlled. It can be used effectively over a long period of time.

  In the above configuration, if the air passage resistance of the second filter medium is lower than the air passage resistance of the first filter medium, most of the air passes through the second filter medium under a low ventilation resistance and is filtered. At the same time, dust is effectively accumulated in the first filter medium.

  Further, in the above configuration, the second filter medium is formed in a conical shape constricted toward the upstream side of the air flow, and the first filter medium is formed in a cylindrical shape so as to be positioned on the outer peripheral side of the second filter medium. It is good to form. When configured in this manner, the conical second filter medium can capture dust effectively in the vicinity of the center of the cylindrical first filter medium and is trapped on the second filter medium. The dust can be distributed and accumulated in the first filter medium along the outer circumferential surface of the second filter medium.

  In addition, in the above configuration, at least the second filter medium is laminated on the surface of the base material layer supporting the shape maintaining function and the base material layer, and has a finer filter than the base material layer. It is good to comprise with the filter layer of a low friction coefficient rather than a material layer, and to arrange | position a filter layer to the upstream of an air flow. In this way, even when the air flow rate is high, the shape of the second filter medium can be maintained, a high filtration function can be maintained, dust can be efficiently filtered by the fine filter mesh, and the filtration can be performed. The dust can be appropriately guided along the surface of the second filter medium toward the first filter medium.

Furthermore, if the second filter medium is arranged on a straight line connecting the air inlet and the air outlet, the air flow in the second filtration channel, which is the main channel, can be secured in the air cleaner.
The invention relating to the air cleaner is characterized in that the air cleaner filter having the above-described configuration is housed in a casing having an air inlet and an air outlet. Therefore, in this air cleaner, an air cleaner having various effects described above can be realized.

  Furthermore, in another invention relating to the air cleaner, the filtration flow path including a filter medium having a conical shape constricted toward the upstream side of the air flow, and the filtration so as to receive dust captured by the filter medium. And a dust receiving part provided on the outer periphery of the downstream side of the material, and a dust exhaust valve provided on the dust receiving part and opened by vibration, the filter medium being a base material carrying a shape maintaining function And a filter layer having a finer filter mesh than the base material layer and having a lower friction coefficient than that of the base material layer, and the filter layer on the upstream side of the air flow. It is characterized by the arrangement.

  Therefore, in this air cleaner, when air flows along the filtration flow path, dust contained in the air is filtered and captured by the conical filter material, and the dust is accumulated in the dust receiving portion. When a vibration is applied to the air cleaner filter as the vehicle equipped with the air cleaner filter travels, the dust discharge valve is opened and dust is discharged from the dust receiving portion to the outside. For this reason, the structure is simple, dust contained in the air can be effectively captured, and the dust can be automatically discharged to the outside along with vibration.

  As described above, according to the present invention, it is possible to effectively filter dust and to obtain an effect of ensuring an air flow rate over a long period of time.

(First embodiment)
Below, 1st Embodiment of this invention is described based on FIGS.
As shown in FIG. 3, a casing 11 of an air cleaner according to this embodiment is attached to a horizontal cylindrical case body 12 having an open end, and an open end of the case body 12 through a clamp 14 so as to be opened and closed. And a cover 13. On one side wall of the cover 13, an air inflow port 15 communicating with the outside air is formed to protrude. An air outlet 16 connected to the intake side of the vehicle engine protrudes from the other side wall of the case body 12, and a cylindrical filter holding cylinder 17 protrudes from the inner surface of the other side wall of the case body 12. Yes.

  As shown in FIGS. 3 and 4, a filter 18 is detachably attached to the filter holding cylinder 17 of the case body 12 through the seal ring 19 in the casing 11. The filter 18 is formed in a conical shape that protrudes and is fixed to the center of one end of the first filter medium 20 having a cylindrical shape as a whole and that is narrowed toward the upstream side of the air flow. The second filter medium 21 is configured. And these filter media 20 and 21 pass in the casing 11 in the 1st filtration flow path 22 of the outer peripheral side which passes along the 1st filter media 20, and the center hole 20a of the 2nd filter media 21 and the 1st filter media 20. The central second filtration channel 23 is formed to extend in parallel. Further, the second filter medium 21 is disposed on a straight line connecting the air inlet 15 and the air outlet 16. The air passage resistance of the second filter medium 21 is formed lower than the air passage resistance of the first filter medium 20.

  As shown in FIGS. 3 and 4, the first filter medium 20 has a cylindrical honeycomb structure as a whole by winding a laminated material 24 composed of a flat filter medium sheet 24 a and a wave-shaped filter medium sheet 24 b in a spiral shape. It is formed to make. A plurality of air passages 25 are defined by the corrugated filter medium sheet 24b between the flat filter medium sheets 24a of the laminated material 24 arranged in a spiral shape. Among these air passages 25, for the first air passages 25a arranged every other one, the end of the second filter material 21 opposite to the attachment side end, that is, the upstream side of the air flow is the sealing material. 26, and the remaining second air passage 25b is sealed by the sealing material 26 at the attachment side end of the second filter material 21, that is, the downstream side of the air flow. And the air which flows through the 1st filtration channel 22 is introduced into each 1st air passage 25a from the one end side of the 1st filter material 20, permeate | transmits the flat filter medium sheet 24a or the waveform filter medium sheet 24b, After being filtered by the flat filter medium sheet 24a or the corrugated filter medium sheet 24b, it is led out from the other end side of the first filter medium 20 toward the intake side of the engine via each second air passage 25b. Yes.

  As shown in FIGS. 3 to 5, the second filter medium 21 is formed so as to form a conical shape as a whole from the fan-shaped filter medium 27. The second filter medium 21 is fixed to the inner peripheral edge of one end of the center hole 20a of the first filter medium 20 by adhering and fixing the base end portion of the conical second filter medium 21 to the center of one end of the first filter medium 20. Projected to the part. In this state, the outer peripheral surface of the cone of the second filter medium 21 is arranged in an inclined state toward the end surface of the first filter medium 20, and the dust D captured on the outer peripheral surface of the cone of the second filter medium 21 is filtered. As the air flows to the flow path 22 side, it is guided and guided to the first filter medium 20 side.

  As shown in FIG. 2, the filter medium 27 includes a base material layer 27a and a filtration layer 27b laminated on the surface of the base material layer 27a. The base material layer 27a is made of a non-woven fabric in which thick synthetic resin fibers are gathered at a low density compared to the filtration layer 27b, has rigidity for shape retention, and carries the shape retention function of the second filter material 21. is doing. The filtration layer 27b is made of a nonwoven fabric that is thin and has a high density of synthetic resin fibers having a lower coefficient of friction than the base material layer 27a, and has a small thickness and a sufficient porosity. Therefore, the filtration layer 27b has finer filter meshes than the base material layer 27a, has a high filtration function, and is not easily clogged. And the 2nd filter medium 21 is arrange | positioned so that the filtration layer 27b may become an upstream, and as shown by the arrow in FIG. 2, the dust in the air flow which passes from the filtration layer 27b side to the base material layer 27a side is shown. Filter.

In this embodiment, the base material layer 27a is made of natural fibers such as pulp, and the filtration layer 27b is made of synthetic fibers such as nylon and polypropylene. The diameter of the fiber which comprises the base material layer 27a is 20-90 micrometers, and the fabric weight of the base material layer 27a is 40-150 g / m < ² >. The diameter of the fibers constituting the filtration layer 27b is 0.01 to 2.5 μm, and the basis weight of the filtration layer 27b is 0.1 to 15 g / m ² .

Next, the operation of the air cleaner configured as described above will be described.
Now, when the air cleaner is connected to the intake side of the vehicle engine and the engine is operated, intake air is introduced into the casing 11 from the air inlet 15, and the first filtration passage 22 of the filter 18. And after flowing along the 2nd filtration channel 23, it is led out of casing 11 from air outlet 16. And when air flows into the 1st filtration channel 22, dust D contained in the air is filtered and captured by the 1st filtration material 20, and air flows into the 2nd filtration channel 23, The dust D contained in the air is effectively filtered and captured by the second filter medium 21 having a fine filter.

  In this case, since the ventilation resistance of the second filter medium 21 is lower than that of the first filter medium 20, most of the air flow passes through the second filter medium 21 and flows through the second filter channel 23. For this reason, most of the dust in the air flow is captured by the second filter medium 21. And the trapped dust D is the 1st filter medium 20 arrange | positioned along the cone outer peripheral surface of the 2nd filter medium 21 with a low friction coefficient by the flow of the air to the 1st filter flow path 22 side. Guided to the side. Therefore, the dust D captured by the second filter medium 21 is accumulated in the entire first filter medium 20.

  As a result, the second filtration flow path 23 provided with the second filter medium 21 is always maintained in a state where an air flow rate is secured, and the dust D accumulates on the first filter medium 20 on the first filtration flow path 22 side. However, there is no possibility that the ventilation resistance of the filter 18 as a whole will greatly increase. Therefore, even if the dust D is accumulated in a large amount in the first filter medium 20, a sufficient air flow rate can be secured on the second filtration flow path 23 side. Therefore, it is not necessary to frequently replace the filter 18 composed of the first filter medium 20 and the second filter medium 21, and can be used effectively over a long period of time.

Therefore, this embodiment has the following effects.
(1) In this embodiment, the dust D trapped on the second filter medium 21 is guided and guided to the first filter medium 20 side and accumulated in the first filter medium 20. For this reason, the air flow rate can always be ensured on the second filtration flow path 23 side, and the possibility that the ventilation resistance is increased can be suppressed, and can be used effectively over a long period of time.

  (2) The air passage resistance of the second filter medium 21 is set lower than the air passage resistance of the first filter medium 20. Therefore, most of the air is filtered through the second filter medium 21 under a low ventilation resistance, and dust is effectively accumulated in the first filter medium 20. Therefore, the dust D can be collected effectively and there is no possibility of impeding the output of the engine.

  (3) Since the 1st filtration flow path 22 and the 2nd filtration flow path 23 are arrange | positioned in parallel, the raise of the passage resistance of the air which passes the inside of an air cleaner can be suppressed, and it can contribute to the engine efficiency improvement.

  (4) The second filter medium 21 is formed in a conical shape that narrows toward the upstream side of the air flow, and the first filter medium 20 is formed in a cylindrical shape so as to be positioned on the outer peripheral side of the second filter medium 21. ing. For this reason, the dust D can be effectively captured in the vicinity of the center portion of the cylindrical first filter medium 20 by the conical second filter medium 21 and the dust captured on the second filter medium 21. D can be distributed and accumulated in the first filter medium 20 along the conical outer peripheral surface of the second filter medium 21. Therefore, the dust D can be effectively captured and accumulated in a large amount, and the long life of the filter 18 can be achieved.

  (5) The second filter medium 21 includes a base material layer 27a carrying a shape maintaining function, a filter mesh finer than the base material layer 27a, and a filter layer 27b having a lower friction coefficient than the base material layer 27a. It is configured. Therefore, even if the flow rate of air is high, the second filter medium 21 is appropriately maintained in shape, and a high filtration function is maintained, and dust can be efficiently filtered by the fine filter mesh. The filtered dust can be smoothly guided along the surface of the second filter medium 21 toward the first filter medium 20.

  (6) Since the second filter medium 21 is arranged on a straight line connecting the air inlet 15 and the air outlet 16 of the casing 11, the air flow in the second filtration channel 23 which is the main channel in the air cleaner. Can be secured.

(Second Embodiment)
Next, a second embodiment of the present invention will be described with a focus on differences from the first embodiment.
In the second embodiment, as shown in FIG. 6, a conical frame-shaped holding frame 31 is bonded and fixed to the inside of the conical second filter material 21, and the second filter material is secured by the holding frame 31. The shape of 21 is held.

Therefore, also in the second embodiment, the same effects as those described in the first embodiment can be obtained. In addition, the second embodiment has the following effects.
(7) Since the second filter medium 21 is reinforced by the holding frame 31, it is possible to suppress the possibility that the second filter medium 21 is deformed during use even when the air flow rate is high. Therefore, in the second embodiment, even a compact configuration can cope with a large amount of air flow.

(Third embodiment)
Next, a third embodiment of the present invention will be described with a focus on differences from the first embodiment.
In the third embodiment, as shown in FIGS. 7 and 8, the first filter medium 20 of the filter 18 is formed by laminating a plurality of laminates 24 each composed of a flat filter medium sheet 24a and a corrugated filter medium sheet 24b. Thus, it is formed so as to form a cuboid multilayer honeycomb structure as a whole. Further, the second filter medium 21 of the filter 18 has a two-layer structure including a base material layer and a filter layer similar to those in the first and second embodiments, and the filter layer is located on the upstream side of the air flow. . The second filter medium 21 is formed in a substantially rectangular shape, and is bonded and fixed to the upper edge of the first filter medium 20 so as to extend in an inclined state toward the upper front. In a state in which the filter 18 is accommodated in the casing 11, a lower first filtration passage 22 passing through the first filter medium 20 and an upper first filter medium passing through the second filter medium 21 are disposed inside the casing 11. Two filtration channels 23 are formed to extend in parallel.

Therefore, also in the third embodiment, substantially the same effect as that described in the first embodiment can be obtained.
(Fourth embodiment)
Next, a fourth embodiment of the present invention will be described with a focus on differences from the first embodiment.

Now, in this 4th Embodiment, as shown in FIG. 9, the 1st filter material 20 in each said embodiment is not provided.
That is, the casing 11 includes a vertical cylindrical case main body 12 and a cover 13 attached to the upper end opening of the case main body 12 through a clamp 14 so as to be opened and closed. An air inflow port 15 extending in the tangential direction is formed on the peripheral side wall of the cover 13 so as to protrude. Accordingly, a swirling flow of air is generated in the casing 11. An air outlet 16 protrudes from the outer surface of the bottom wall of the case body 12, and a filter holding cylinder 17 protrudes from the inner surface of the bottom wall.

  In the casing 11, the filter holding cylinder 17 of the case main body 12 has a conical shape, and a filter medium 32 constituting the filter is detachably attached. This filter medium 32 consists of a base material layer and a filter layer similarly to the 2nd filter medium 21 of each said embodiment, and is positioning the filter layer in the upstream of an air flow. And the filtration flow path 33 which passes the filter medium 32 in the casing 11 is formed, and when air flows along this filtration flow path 33, the dust D contained in the air is filtered and captured by the filter medium 32. It has become so.

  An annular dust receiving portion 34 is formed on the outer peripheral portion of the bottom wall of the case body 12, and the inner bottom surface is formed so as to incline downward toward one side portion. The dust D captured by the conical filter medium 32 is collected by the dust receiving portion 34. A dust discharge valve 35 is disposed at the lower end of the dust receiving portion 34. When vibration is applied to the air cleaner as a vehicle equipped with the air cleaner travels, the dust discharge valve 35 resists its elasticity. Thus, the dust D on the dust receiving portion 34 is discharged to the outside by being released from the closed state.

  For this reason, in the fourth embodiment, the air that has flowed into the casing 11 from the air inlet 15 is swirled in the casing 11, a part of the dust D is separated by centrifugal force, and the remaining dust D is filtered. Filtered by material 32. These dusts D are collected in the dust receiver 34 and accumulated on the dust discharge valve 35. Then, the dust discharge valve 35 is opened by the vehicle vibration or the like, and the dust D is discharged.

Therefore, the air cleaner according to the fourth embodiment has the following effects.
(8) Since the filter is constituted by one filter medium 32, the structure of the filter is simple.

(9) The dust D can be automatically discharged to the outside along with the vibration, does not require cleaning, and is maintenance-free.
(Example of change)
In addition, this embodiment can also be changed and embodied as follows.

  In the first and second embodiments, the shape or structure of the second filter medium 21 is changed. For example, FIG. 10 shows the second filter medium 21 formed in a cylindrical shape whose tip forms a hemisphere, and FIG. 11 shows the second filter medium 21 whose tip forms a hemisphere and the side wall shape of the peripheral wall. It has an arc shape with a large diameter. Moreover, FIG. 12 forms the 2nd filter material 21 in the cone shape which the side wall shape of the surrounding wall curves inside. In FIG. 13, spiral fins 21 c are provided on the outer peripheral surface of the second filter medium 21 having a conical shape so that a swirling flow is generated.

  In the first to third embodiments, the flat filter medium sheet 24 a and the corrugated filter medium sheet 24 b of the first filter medium 20 have a two-layer structure similar to the second filter medium 21. In this case, the filtration layer is positioned upstream of the air flow. In this way, the accumulated dust D can be easily cleaned and removed by the function of the two-layer filter medium having a low friction coefficient and a filter layer that is not easily clogged, thereby reducing maintenance work.

The simplified perspective view which shows the air cleaner of 1st Embodiment. The expanded sectional view of the 2nd filter medium. Sectional drawing which shows the air cleaner of 1st Embodiment. The perspective view which decomposes | disassembles and shows the air filter of the air cleaner of FIG. The perspective view which shows the preparation method of the 2nd filter material of the air filter of FIG. The disassembled perspective view which shows the 2nd filter medium of the air filter in the air cleaner of 2nd Embodiment. Sectional drawing which shows the air cleaner of 3rd Embodiment. The perspective view which decomposes | disassembles and shows the air filter of the air cleaner of FIG. Sectional drawing which shows the air cleaner of 4th Embodiment. The simplified perspective view which shows the air cleaner of a modification. The simplified perspective view which shows the air cleaner of another modification. Furthermore, the simplified perspective view which shows the air cleaner of another modification. Furthermore, the simplified perspective view which shows the air cleaner of another modification.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 11 ... Casing, 12 ... Case main body, 13 ... Cover, 15 ... Air inflow port, 16 ... Air outflow port, 18 ... Filter, 20 ... 1st filter medium, 21 ... 2nd filter medium, 22 ... 1st filter flow path , 23 ... 2nd filtration flow path, 24 ... Laminated material, 24a ... Flat filter medium sheet, 24b ... Wave-shaped filter medium sheet, 27 ... Filter medium, 27a ... Substrate layer, 27b ... Filtration layer, 31 ... Holding frame, 32 ... Filter medium, 33 ... filtration flow path, 34 ... dust receiving part, 35 ... dust exhaust valve, D ... dust.

Claims (7)

A first filter material that forms a first filtration channel and a second filter material that forms a second filtration channel are arranged adjacent to each other, and dust trapped on the second filter material is placed on the first filter material side. An air cleaner filter, wherein the second filter medium is disposed in an inclined state toward the first filter medium so as to be guided and guided. 2. The air cleaner filter according to claim 1, wherein an air passage resistance of the second filter medium is lower than an air passage resistance of the first filter medium. The second filter medium is formed in a conical shape that narrows toward the upstream side of the air flow, and the first filter medium is formed in a cylindrical shape so as to be positioned on the outer peripheral side of the second filter medium. The filter for air cleaners of Claim 1 or 2. At least a second filtering material is laminated on the surface of the base material layer supporting the shape maintaining function, and has a finer filter than the base material layer, and has a lower friction coefficient than the base material layer. The filter for air cleaners as described in any one of Claims 1-3 comprised by the layer and arrange | positioned the filtration layer in the upstream of the air flow. An air cleaner, wherein the air cleaner filter according to any one of claims 1 to 4 is housed in a casing having an air inlet and an air outlet. The air cleaner according to claim 5, wherein the second filter medium is disposed on a straight line connecting the air inlet and the air outlet. A filter passage having a conical filter medium that narrows toward the upstream side of the air flow, and a dust receiver provided on the outer periphery on the downstream side of the filter medium so as to receive dust trapped by the filter medium And a dust exhaust valve that is provided at the dust receiving portion and is opened by vibration, and the filter medium is laminated on the surface of the base material layer carrying the shape maintaining function. An air cleaner comprising a filter layer finer than the base material layer, a filter layer having a lower friction coefficient than the base material layer, and the filter layer disposed on the upstream side of the air flow.

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