JP2013002416A - Air blowing device and air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve blowing efficiency of an air blowing device with which an axial flow fan is arranged within a tubular body, to increase the concentration of ion or volatile medicines blown from the air blowing device and an air conditioner including an ion generating part or a medicine discharge part, and to reduce the air blowing device in size as a whole.SOLUTION: An axial flow fan 2 is arranged in one terminal part within a tubular body 1 which is cylindrical, and another terminal side in the tubular body 1 is used as a ventilation path 4 in which air sent in a rotary axis direction of the axial flow fan 2 by the axial flow fan 2 is ventilated in the rotary axis direction. A partition wall 5 is provided which partitions the ventilation path 4 into a central part 4a and an edge part 4b between the axial flow fan 2 and an outlet of the ventilation path 4. A stream of air ventilated through the edge part 4b and blown from an outlet 1b to the outside is suppressed from flowing back to the central part 4a of the ventilation path 4, and an ion generating part 6 is accommodated within the partition wall 5, thereby reducing the device in size as a whole.

Description

  The present invention relates to a blower device including an axial fan, and an air conditioner including the blower device and an ion generation unit or a drug discharge unit.

In recent years, air conditioners including an ion generator that discharges in the air and discharges charged particles into the air have been widely sold (see, for example, Patent Documents 1, 2, and 3). In general, an air conditioner including an ion generation unit includes a discharge electrode that generates ions and a counter electrode that is installed opposite to the discharge electrode and stably discharges the discharge electrode and the counter electrode. Ions are generated by applying high voltage electricity in between. The ions generated at the discharge electrode include positive ions having a positive charge and negative ions having a negative charge, and various types of ions are generated depending on the applied voltage.
In order to efficiently send out the generated ions to the outside, it is common practice to apply an air flow to the ion generation unit, and various types of blowers are used.

  The air blower is characterized by the air flow sent out by each type, and there is a method suitable for the air blower used also in the method of installing the ion generator.

  In Patent Document 1, an axial blower having an axial fan is used, and a shaft in a ventilation cylinder is used to ventilate air sent in the direction of the rotation axis of the axial fan by the axial fan. An air conditioner (beauty device) is disclosed in which an ion generation unit is arranged in the center of the ventilation tube on the side of the flow fan and the outlet of the ventilation tube is narrowed.

  In Patent Document 2, a centrifugal blower having a sirocco fan is used, and one side wall of the ventilation path is provided in the middle of the ventilation path in which air sent in the tangential direction of the sirocco fan is ventilated in the tangential direction by the sirocco fan. An air conditioner in which an ion generating part is arranged in the part is disclosed.

  In Patent Document 3, an axial blower having an axial fan or a centrifugal blower having a turbo fan is used to ventilate the air sent by the axial fan or turbo fan in a spiral manner. An air conditioner that increases the concentration of ions sent to the ventilating tube by arranging an ion generating part on one side wall of the ventilating tube and generating a spiral airflow in the ventilating tube. A machine is disclosed.

  FIG. 8A is a schematic longitudinal front view showing a configuration of an air conditioner previously developed by the applicant of the present invention, and FIG. 8B is a schematic longitudinal side view. This air conditioner has an axial flow fan at the lower part in a casing 90 having a cylindrical inner wall portion 90a penetrating vertically and a cylindrical outer wall portion 90c connected to the upper end of the cylindrical inner wall portion 90a via an enlarged diameter step portion 90b. The blower having 91 is housed, and the bottom of the housing 90 is closed by a bottom plate 92 having a suction port 92a at the center thereof. The casing 90 is a cylindrical ventilation passage 93 between the blower in the cylindrical inner wall portion 90a and the enlarged diameter step portion 90b, and a lattice for adjusting the direction of air blown from the outlet 93a of the ventilation passage 93 A shaped air conditioning body 94 is arranged in the diameter-expanded step 90b. In the middle of the ventilation direction of the ventilation path 93, a hole 90d is formed in one side portion of the cylindrical inner wall 90a, and the ion generator 95 is held in the hole 90d.

FIG. 9 is a perspective view showing the configuration of the ion generator 95. The ion generator 95 has a needle-like electrode 95a and a counter electrode 95b as positive ion generators, and has a needle-like electrode 95c and a counter electrode 95d as negative ion generators, and each of the needle-like electrodes 95a and 95c. And high voltage electricity is applied between the counter electrodes 95b and 95d, and positive ions H ⁺ (H ₂ O) m (m is an arbitrary natural number) and negative ions O ₂ ⁻ (H ₂ O) n (n is an arbitrary number). Natural number). When positive ions H ⁺ (H ₂ O) m and negative ions O ₂ ⁻ (H ₂ O) n are released into the air, they attach to the surface of bacteria or viruses floating in the air and cause a chemical reaction. It is known that the generated hydroxyl radicals OH and hydrogen peroxide H ₂ O ₂ kill bacteria and inactivate viruses.

JP 2011-002210 A JP 2010-080425 A JP 2006-000183 A

  An air conditioner (beauty device) in which an ion generation unit is arranged in the center on the axial flow fan side in the ventilation tube whose outlet is narrowed as in Patent Document 1, and as shown in FIGS. 8A and 8B In the air conditioner in which the ion generating part 95 is arranged on one side wall part of the ventilation path 93 that ventilates the axial flow fan 91 in the rotation axis direction, the air blown out from the outlet 93a of the ventilation path 93 A part of the airflow flows backward from the outlet 93a to the central portion of the ventilation passage 93, and the backflowed air is again wound around the peripheral portion and blown out again from the outlet 93a, so that the blowing efficiency is lowered. However, there has been a problem that the air conditioner becomes large in order to obtain a constant blowing amount.

  By the way, in patent document 1, although restrict | squeezing the exit of a ventilation pipe | tube, it is made to suppress that a part of airflow of the air blown from the exit to the outside flows back into a ventilation pipe | tube, By restricting the outlet, the amount of air blown from the outlet is reduced, and the blowing resistance is increased so that noise is likely to occur. Therefore, it is preferable not to restrict the outlet.

  In an air conditioner equipped with an axial fan, a part of the airflow blown out from the outlet to the outside flows back into the ventilation cylinder because of the characteristics of the propeller of the axial fan. However, because of its characteristics, the propeller can easily obtain a relatively large air volume, and is therefore often used in equipment with a small pressure loss in the ventilation cylinder. Also, the airflow of air sent out by the propeller is spiral, and the ions generated in the ion generator can be blown in a spiral to increase the concentration of ions, so it is used for an air conditioner equipped with an ion generator. Is preferred.

  FIG. 10A is a plan view showing the configuration of the propeller 100 included in the blower, and FIG. 10B is a front view showing the configuration of the propeller 100 included in the blower. The propeller 100 has a plurality of propeller blades 102 equally arranged on the peripheral surface of the boss portion 101, and rotates in the direction of the arrow. The propeller blades 102 are shaped such that the blade surfaces of the propeller blades 102 are lowered in the rotational direction and the tip 102a is lowered to the opposite side of the delivery direction, so that the delivery air is pushed upward by the propeller blades 102 and also pushed in the rotation direction of the propeller 100 Further, due to the viscosity of the air, the centrifugal force is received by rotating together with the propeller 100, so that the force is applied in the outward direction as viewed from the direction of the rotation axis. As a result, the airflow of the air sent out by the propeller 100 is formed in a spiral shape in the rotation direction of the propeller 100 and becomes an airflow spreading outward in the rotation axis direction.

  Further, the boss portion 101 to which the base end of the propeller blade 102 is fixed has a substantially cylindrical shape, and the boss portion 101 does not generate a force for sending air in the rotation axis direction. Airflow is not generated on the leeward side.

  Since the propeller 100 included in the axial fan 91 has the above-described characteristics, in the air conditioner of FIGS. 8A and 8B including the axial fan 91, the air blower disposed in the lower part of the housing 90 has a ventilation direction. A spiral-shaped air stream that is ventilated while spreading toward is sent out. The spiral airflow that is ventilated while spreading hits the road wall 93b of the ventilation path 93, ventilates along the road wall 93b to the upper outlet 93a, and entrains ions generated by the ion generator 95 arranged in the middle of the ventilation. Then, the air is blown out from the air conditioning body 94 at the outlet 93a.

  The spiral airflow of the air blown from the air conditioning body 94 of the outlet 93a tends to gather at the peripheral portion of the outlet 93a, and there is not much airflow in the central portion of the outlet 93a that is directly above the boss portion 101 of the propeller 100. A state that does not occur. Further, in a severe situation, the airflow may flow backward at the center of the outlet 93a. As a result, the amount of air blown from the outlet 93a to the outside decreases, and the blowing efficiency decreases.

  FIG. 11 is a schematic diagram showing a situation in which the blown air volume decreases in the previously developed air conditioner. The airflow sent by the propeller 100 of the axial fan 91 passes through the ventilation path 93 toward the upper outlet 93a, and the blowout airflow A exists at the peripheral edge of the outlet 93a. Since the blown airflow A has a flow velocity, the pressure in the vicinity of the blown airflow A portion is reduced by Bernoulli's law. On the other hand, since the extension region 93c of the boss 101 of the propeller 100 is almost atmospheric pressure, the atmospheric pressure is not lowered. Due to such a difference in atmospheric pressure, an air flow B is generated from the extended region 93 c of the boss portion 101 toward the peripheral edge of the ventilation path 93. The faster the flow velocity of the air flow blown out, the larger the pressure difference and the higher the flow velocity of the air flow B flowing backward.

  In addition, as shown in Patent Documents 2 and 3, and FIGS. 8A and 8B, in the air conditioner in which the ion generation unit 95 is arranged on one side wall portion of the ventilation path 93 in the middle of the ventilation path 93. Since the outer shape is obtained by adding the dimension of the ion generating part 95 to the dimension of the ventilation path 93, there is a design restriction on the downsizing of the air conditioner.

  This invention is made | formed in view of such a situation, and the main objective is to make it possible to raise the blowing efficiency of the air blower which has an axial fan and a ventilation cylinder, and the other objective is An object of the present invention is to increase the concentration of ions or volatile chemicals blown out by an air conditioner having an air blower and an ion generation unit or chemical release unit, and to reduce the overall size.

  The blower according to the present invention includes a ventilation tube that allows air sent from the axial fan to the rotation axis direction of the axial fan to flow in the rotation axis direction, and blows the air from the outlet of the ventilation tube to the outside. In the blower device to be provided, a partition wall that partitions the inside of the ventilation tube into a central part and a peripheral part between the axial fan and the outlet is provided.

  In this invention, since the air sent out by the axial flow fan is blown along the partition wall in the ventilation tube and is not blown through the central portion, one of the blown airflow is not concerned regardless of the flow velocity of the blown airflow. The part can be prevented from flowing back into the ventilation tube.

Further, in the blower according to the present invention, the axial fan has a propeller in which a plurality of propeller blades are equally arranged on a peripheral surface of the boss portion, and the partition wall is between the boss portion and the outlet. It is preferable that the length is approximately equal to the length.
In this invention, the inside of the ventilation cylinder between the boss part and the outlet is divided into a central part and a peripheral part, and since the central part in the ventilation cylinder is not ventilated, a part of the blown airflow enters the ventilation cylinder. Backflow can be suppressed.

In the air blower according to the present invention, it is preferable that the ventilation tube and the partition wall have a substantially cylindrical shape.
According to the present invention, the spiral airflow sent by the propeller of the axial fan can be smoothly ventilated, and the relatively large diameter and lightweight partition wall can be easily arranged in the air cylinder. It is possible to reduce the weight while having the partition wall, and the cost can be reduced.

In the air blower according to the present invention, it is preferable that the boss portion has a substantially cylindrical shape, and the partition wall has an outer diameter equal to or larger than the diameter of the boss portion.
In this invention, since the area | region where a part of blowing airflow flows backward can be reduced, the backflow of blowing airflow can be suppressed further.

Moreover, it is preferable that the air blower according to the present invention has a wind conditioning body that adjusts the direction of air blown out from the outlet to the outside, and the partition wall is close to the wind conditioning body.
In this invention, since it can prevent backflow from the center part of an air conditioning body, in an air blower provided with an air conditioning body, it further suppresses that a part of blowing airflow flows back into a ventilation cylinder. Can do.

In the blower according to the present invention, it is preferable that the partition wall has a configuration in which the outlet side portion has a larger diameter than the axial flow fan side portion.
In this invention, since the area | region where a part of blowing airflow flows backward can be reduced further, the backflow of blowing airflow can be suppressed further.

Moreover, the air conditioner which concerns on this invention is provided with the air blower of the invention mentioned above, and the ion generation part which is distribute | arranged to the said partition wall and generates ion.
In the present invention, since the ion generation part is arranged in the central region in the ventilation cylinder partitioned by the partition wall, the ion generation part is provided and the backflow of the blown airflow can be prevented. The air conditioner can be downsized.

Moreover, the air conditioner which concerns on this invention is provided with the ventilation apparatus of the invention mentioned above, and the chemical | medical agent discharge | release part distribute | arranged to the said partition wall and discharge | releases a volatile chemical | medical agent.
In this invention, since the medicine discharge portion is arranged in the central region in the ventilation cylinder partitioned by the partition wall, it has an axial fan and a medicine discharge portion, and can prevent backflow of the blown airflow. The air conditioner can be downsized.

In the air conditioner according to the present invention, it is preferable that the partition wall has a substantially cylindrical shape, and the ion generation unit or the drug discharge unit is arranged in the partition wall.
In this invention, since the ion generating part or the drug discharging part is provided in the partition wall that partitions the inside of the ventilation cylinder into the center part and the peripheral part, the axial flow fan and the ion generating part or the drug discharging part are provided. The air conditioner that can prevent the backflow of the blown airflow can be further reduced in size.

Further, in the air conditioner according to the present invention, the partition wall has a hole penetrating in a radial direction from a position facing the ion generation unit or the drug discharge unit, and the ion generation unit or the drug discharge unit from the hole. Is preferably exposed in the ventilation tube.
In this invention, the ions generated by the ion generation part or the volatile chemicals released by the drug release part can be discharged from the hole of the partition wall to the peripheral part in the ventilation tube, and the spiral airflow is generated. Smooth ventilation in the ventilation cylinder.

Moreover, it is preferable that the air conditioner according to the present invention has a configuration in which a plurality of the ion generators are arranged apart from each other in the rotation axis direction of the axial fan.
In the present invention, the spiral airflow of air sent out by each of the plurality of propeller blades of the propeller of the axial fan can send out the ions generated by each of the ion generators at different delivery times. As a result, the ion generator that generates positive ions and the ion generator that generates negative ions are arranged apart from each other, so that the positive ions and the negative ions can be blown outside in a state where mixing of the positive ions and the negative ions is avoided. Can be put out.

  According to the present invention, the partition wall that divides the inside of the ventilation cylinder into the central portion and the peripheral portion allows the spiral air flow sent out by the propeller of the axial fan to pass through the peripheral portion without passing through the central portion. Therefore, it is possible to suppress a part of the airflow blown out from the outlet of the ventilation tube from flowing back into the ventilation tube, and to prevent a reduction in the blowing efficiency of the blower.

  Further, according to the present invention, since the ion generating part or the drug discharging part is arranged on the partition wall that partitions the inside of the ventilation cylinder into the central part and the peripheral part, the axial flow fan and the ion generating part or the drug discharging part are provided. The air conditioner can be downsized without deteriorating the air conditioning function.

  Further, according to the present invention, the spiral air flow sent out by the propeller of the axial fan causes the ions generated by the ion generating part or the volatile chemicals released by the drug releasing part to flow and blows out from the outlet of the ventilation tube. The ion or volatile drug concentration to be delivered can be substantially increased by suppressing the flow of the ion or drug that has flown back to the central portion in the ventilation cylinder.

It is a typical longitudinal section front view showing the composition of the air harmony machine concerning the present invention. It is a typical longitudinal section side view showing composition of an air harmony machine concerning the present invention. It is typical explanatory drawing which shows the state which blows off from the exit of the air conditioner which concerns on this invention. It is a typical longitudinal section front view showing other composition of the air harmony machine concerning the present invention. It is a typical longitudinal section front view showing other composition of the air harmony machine concerning the present invention. It is a perspective view showing composition of a medicine discharge part with which an air harmony machine concerning the present invention is provided. It is a typical sectional view showing composition of a medicine discharge part with which an air harmony machine concerning the present invention is provided. A is a schematic longitudinal sectional front view showing the configuration of the previously developed air conditioner, and B is a schematic longitudinal sectional side view showing the configuration of the previously developed air conditioner. It is a perspective view which shows the structure of an ion generation part. A is a front view showing the configuration of the propeller of the axial fan included in the blower, and B is a side view showing the configuration of the propeller of the axial fan included in the blower. In the air conditioner developed previously, it is a schematic diagram which shows the condition where the blowing air volume reduces.

Embodiment 1
FIG. 1 is a schematic longitudinal sectional front view showing the configuration of an air conditioner according to the present invention, and FIG. 2 is a schematic longitudinal sectional side view showing the configuration of the air conditioner. This air conditioner has a cylindrical shape penetrating vertically, and has a cylindrical body 1 having an inlet 1a at the lower end and an outlet 1b at the upper end, and an axial fan that is rotatably disposed at the lower portion of the cylindrical body 1. 2, a fan case 3 that rotatably supports the axial fan 2, and an airflow path 4 formed between the axial fan 2 and the outlet 1 b in the cylindrical body 1, a central portion 4 a and a peripheral edge A partition wall 5 having a cylindrical shape that is partitioned into a portion 4b, and an ion generator 6 that is housed and held in the partition wall 5, and the inside of the cylinder 1 from the inlet 1a of the cylinder 1 by the rotation of the axial fan 2 The air sucked into the air passes through the ventilation path 4, and the ions generated in the ion generating part 6 are taken in and blown out from the outlet 1b. The cylinder 1, the axial fan 2 and the fan case 3 constitute a blower.

  An inward flange 1c having an inlet 1a is provided at the lower end of the cylindrical body 1, and an air conditioning body 7 for adjusting the direction of air blown out from the outlet 1b is attached to the upper end of the cylindrical body 1. Yes. The air conditioner 7 is provided with a lattice-like partitioning portion 7b in an annular portion 7a.

  The axial fan 2 is the same as that shown in FIGS. 10A and 10B, and has a propeller 20 in which three propeller blades 22 are equally arranged on the peripheral surface of a boss portion 21 having a substantially cylindrical shape, and an arrow Rotate in the direction of. The propeller blade 22 has a shape in which the tip of the blade surface is lowered in the rotation direction, and the air to be sent out is pushed upward (in the direction of the rotation axis) and also pushed in the rotation direction of the propeller 20, and the air Since the centrifugal force is received by rotating together with the propeller 20 due to the viscosity of the propeller 20 and the force is applied in the outward direction when viewed from the direction of the rotation axis, the air flow sent out by the propeller 20 spirals toward the rotation direction of the propeller 20. At the same time, the airflow spreads outward in the ventilation direction. The spiral airflow in the ventilation path 4 in the cylindrical body 1 hits the circumferential surface of the ventilation path 4, is ventilated along the outer circumferential surface of the partition wall 5 to the outlet 1 b, and is arranged in the middle of the ventilation path 4. Ions generated in the generator 6 are entrained and blown out from the air conditioning body 7 at the outlet 1b.

  Since the spiral airflow is generated for each propeller blade 22 as schematically indicated by “a”, “b”, and “c” in FIGS. 1 and 2, the number of spirals corresponding to the number of propeller blades 22 is generated. The airflow moves in the ventilation path 4 in parallel. That is, the respective spiral airflows are stacked to form a layer and move toward the outlet 1b.

  Since the boss portion 21 has a substantially cylindrical shape, and the boss portion 21 does not generate a force for sending air in the rotation axis direction, the central portion 4a (the boss portion) facing the boss portion 21 of the ventilation path 4 in the cylindrical body 1 is used. No airflow is generated on the leeward side of 21.

  The fan case 3 is arranged coaxially with the rotational axis of the axial fan 2, has a cylindrical shape covering the outer periphery of the axial fan 2, and is supported by the flange 1 c of the cylindrical body 1.

  The ventilation path 4 is formed between the boss portion 21 and the outlet 1 b of the axial fan 2 in the cylindrical body 1, and allows the air sent from the axial fan 2 to flow in the rotational axis direction of the axial fan 2. It ’s like that.

  The partition wall 5 has a length substantially equal to the length between the boss portion 21 and the outlet 1 b and has a cylindrical shape having a thickness (outer diameter) equal to or larger than the diameter of the boss portion 21. Is arranged coaxially with the rotational axis of the axial fan 2, and the upper end is in contact with the lower surface of the annular portion 7 a of the air conditioning body 7, in other words, close to the lower surface of the annular portion 7 a, and the partition wall 5 of the ventilation path 4 The inner side is the central part 4a, and the outer periphery of the partition wall 5 is the peripheral part 4b.

  A substantially rectangular hole 51 penetrating in the radial direction is formed in the middle of the partition wall 5 in the longitudinal direction, and the ion generating part 6 is attached to the edge of the hole 51 by fitting.

  The ion generator 6 is the same as that shown in FIG. 9, and is a positive ion generator 61 that generates positive ions, and a negative ion that generates negative ions at a position spaced apart from the positive ion generator 61 in the direction of the rotation axis. An ion generator 62, a positive ion generator 61, and a holding body 63 that holds the negative ion generator 62. The holding body 63 is attached to the edge of the hole 51, and the positive ion generating part 61 and the negative ion generating part 62 are arranged side by side in the rotational axis direction.

  The positive ion generation unit 61 and the negative ion generation unit 62 include a discharge needle that faces the peripheral portion 4b from the hole 51, an induction electrode ring that surrounds the discharge needle, and a voltage application unit that applies a voltage to the discharge needle and the induction electrode ring. The voltage applying unit applies a voltage to the discharge needle and the induction electrode ring, so that the discharge needle corona discharges to generate positive ions and negative ions.

  The air conditioner configured as described above is placed on a gantry so that the air in the living room can be sucked from the inlet 1a of the cylinder 1. The propeller 20 of the axial fan 2 is rotated in the direction of the arrow in FIGS. 1 and 2 by driving means such as an electric motor, and air in the living room is sucked into the cylinder 1 from the inlet 1a, and the propeller 20 is moved in the direction of the rotation axis. It passes through and is sent to the peripheral edge 4 b of the ventilation path 4. At this time, there is almost no airflow in the central portion 4a of the portion of the ventilation path 4 facing the boss portion 21 of the propeller 20 in the rotation axis direction, and the air sent to the peripheral portion 4b is separated by the partition wall 5 into the central portion 4a. Ventilation is prevented and blown out from the air conditioning body 7 along the peripheral edge 4b. The air stream thus blown tends to gather at the peripheral portion of the air conditioner 7, and there is a blown air current at the peripheral portion of the air conditioner 7, and the air is blown out at the central portion facing the boss portion 21 of the propeller 20 in the rotation axis direction. There will be no airflow.

  FIG. 3 is a schematic explanatory view showing a state where the air is blown out from the outlet 1b of the air conditioner. Since the blown airflow has a flow velocity, the air pressure is reduced in the blown airflow region at the periphery of the air conditioning body 7. On the other hand, the area where there is no blowing airflow in the central portion of the air conditioner 7 is almost atmospheric pressure, and therefore the atmospheric pressure does not decrease. Due to the difference in atmospheric pressure between the blown air flow region and the region without the blown air flow, an air flow B directed from the extended region of the partition wall 5 toward the blown air flow A is generated in the region outside the air conditioning body 7. The higher the flow velocity of the blown airflow, the larger the pressure difference and the faster the airflow B flowing backward. However, in the ventilation path 4 inside the air conditioning body 7, a cylindrical partition wall 5 is provided to partition the ventilation path 4 into a central part 4a and a peripheral part 4b, and the central part 4a and the peripheral part 4b. Is maintained by the partition wall 5, so there is no airflow B flowing backward.

  Thus, since it can prevent that the airflow of the air blown outside from the air conditioning body 7 of the exit 1b flows back to the ventilation path 4, the fall of blowing efficiency can be prevented.

  In the air conditioner shown in FIGS. 1 to 3, the partition wall 5 that partitions the ventilation path 4 in the cylindrical body 1 into a central part 4 a and a peripheral part 4 b has a cylindrical shape, and a hole 51 formed in the partition wall 5. Since the ion generating unit 6 is accommodated in the air conditioner, the air conditioner having the axial fan 2 and the ion generating unit 6 can be downsized without reducing the function.

  The ion generator 6 includes a spiral air flow “a” generated for each propeller blade 22 of the propeller 20 because the positive ion generator 61 and the negative ion generator 62 are spaced apart from each other in the rotational axis direction of the axial fan 2. ”,“ I ”,“ U ”are stacked in the ventilating cylinder 4 to form a layer, and when moving toward the outlet 1b, the spiral airflow of“ A ”contains negative ions, and the spiral airflow of“ U ” While positive ions are included, positive ions and negative ions are blown out from the air conditioning body 7 at the outlet 1b in a state where mixing of the positive ions and the negative ions is avoided. Moreover, since the partition wall 5 can prevent the airflow blown to the outside from the air conditioning body 7 from flowing back to the ventilation path 4, the number of ions disappearing in the ventilation path 4 can be reduced. In particular, the number of ions to be sent to the outside from the air conditioner 7 at the outlet 1b can be increased without increasing the air conditioner or the blower. Table 1 shows the number of ions sent out by the air conditioner according to the present invention and the conventional air conditioner measured at the air conditioning body 7 portion of the outlet 1b.

  In the air conditioner according to the present invention, positive ions increased by 2.5% and negative ions increased by 16% compared to the conventional air conditioner.

Embodiment 2
FIG. 4 is a schematic longitudinal sectional front view showing another configuration of the air conditioner according to the present invention. In this air conditioner, instead of the partition wall 5 having an equal diameter extending over the entire length partitioning the ventilation path 4 in the cylindrical body 1, the outlet 1b side portion has a larger diameter than the axial flow fan 2 side portion. The partition wall 50 formed in the structure partitions the ventilation path 4 in the cylindrical body 1 into a central part 4a and a peripheral part 4b.

  The partition wall 50 is connected to the boss portion 21 of the propeller 20 and has a small diameter cylindrical portion 50a, an enlarged diameter cylindrical portion 50b continuous to the small diameter cylindrical portion 50a, and the enlarged diameter cylindrical portion 50b. And a large-diameter cylindrical portion 50c having a large diameter so as not to limit the width of the airflow of air blown from, and is formed to have a length substantially equal to the length between the boss portion 21 and the outlet 1b. The partition wall 50 is disposed coaxially with the rotational axis of the axial fan 2 on the center side of the ventilation path 4, and the end of the large-diameter cylindrical portion 50 c is substantially in contact with the lower surface of the annular portion 7 a of the air conditioning body 7. A hole 51a is formed in the middle of the partition wall 50 in the longitudinal direction, and the ion generating part 6 is accommodated in the hole 51a.

In this configuration, the outlet 1b side sectional area of the peripheral edge 4b in the ventilation path 4 is narrower than the axial fan 2 side sectional area, and the final flow velocity of the airflow passing through the ventilation cylinder 4 is increased. However, since the airflow of the air sent out by the propeller 20 is a spiral shape that spreads outward and is ventilated in the direction of the rotation axis, the diameter of the airflow blown from the air conditioning body 7 at the outlet 1b is made large enough not to limit. This leads to a reduction in the region where the blown airflow flows back to the ventilation path 4, and the backflow of the blown airflow can be further eliminated.
Since other configurations and operations are the same as those of the first embodiment, the same components are denoted by the same reference numerals, and detailed description thereof and description of operations and effects are omitted.

Embodiment 3
FIG. 5 is a schematic longitudinal front view showing another configuration of the air conditioner according to the present invention. In this air conditioner, instead of providing the ion generator 6 on the partition wall 5 that partitions the ventilation path 4 in the cylindrical body 1 into a central part 4a and a peripheral part 4b, a drug release part 8 that releases a volatile drug. Is disposed on the partition wall 5.

  FIG. 6 is a perspective view showing the configuration of the drug release portion 8, and FIG. 7 is a schematic cross-sectional view showing the configuration of the drug release portion 8. The medicine discharge section 8 is provided with a pellet 81 impregnated with any one of volatile general bactericides, insecticides, fungicides, deodorants, or a fragrance that simply emits fragrance, and discharge holes 82a. The container 82 is accommodated in the hole 51 formed in the partition wall 5 by fitting, and the volatile drug released from the discharge hole 82a to the peripheral portion 4b is removed from the peripheral portion 4b. Ventilated air is involved.

In this configuration, the volatile agent is blown out into the room by the spiral airflow of the air sent out by the propeller 20, as in the case where the ion generator 6 is provided.
Since other configurations and operations are the same as those in the first and second embodiments, the same components are denoted by the same reference numerals, and the detailed description and description of the operations and effects are omitted.
Further, a partition wall 50 may be used instead of the partition wall 5.

  In the embodiment described above, the air passage 4 is formed in the cylindrical body 1 that penetrates vertically, and the air is blown upward. It is good also as a structure which makes the inside of the cylinder 1 a ventilation path, and blows off air diagonally upward, and makes it the structure which blows off the air to the ventilation direction in the cylinder 1 arranged in the horizontal direction, The direction in which the air is blown is not particularly limited.

  In the embodiment described above, the cylindrical partition wall 5 is configured to partition the ventilation path 4 in the cylindrical body 1. However, for example, a columnar partition wall or one end is closed. A partition wall having a cylindrical shape at the bottom may be configured to partition the ventilation path 4. In the case of a partition wall having a cylindrical shape, there is no space in the central portion 4a of the ventilation path 4, but the region of the central portion 4a facing the boss portion 21 of the axial fan 2 originally does not have much airflow. Therefore, there is no problem even if there is no space in the central portion 4a. In the case of a partition wall having a cylindrical shape, a recess for accommodating the ion generating part 6 or the drug discharge part 8 or a hole penetrating in the radial direction is provided on the peripheral surface of the partition wall. Moreover, the partition wall may be a polygon such as a hexagon or an octagon other than a circle.

  Moreover, in embodiment described above, the partition walls 5 and 50 which have a length substantially equal to the length between the boss | hub part 21 and the exit 1b are used, and the upper end of the partition walls 5 and 50 is the annular part 7a of the air conditioning body 7. In addition to the configuration close to the lower surface, a partition wall longer than the length between the boss portion 21 and the outlet 1b is used, and the upper end of the partition wall reaches the upper surface of the ring-shaped air conditioning body, or the air conditioning body It is good also as a structure which protrudes from the outside.

  The air conditioner according to the present invention may be configured to include at least one of a cooling function and a heating function.

  According to the present invention, in the air conditioner using the axial flow fan 2, it is possible to prevent the airflow in the vicinity of the air outlet from flowing backward, thereby reducing the wasteful work of the axial flow fan 2. That's all about saving energy. In addition, functional means such as aroma means and drug diffusion means can be accommodated in a space secured on the downstream side of the boss portion 21 of the axial fan 2, which is effective for downsizing the entire device.

DESCRIPTION OF SYMBOLS 1 Cylindrical body 1b Outlet 2 Axial fan 20 Propeller 21 Boss part 22 Propeller blade | wing 4a Center part 4b Peripheral part 5, 50 Partition wall 51, 51a Hole 6 Ion generation part 7 Air conditioning body 8 Drug release part

Claims (11)

  In the blower apparatus, comprising a ventilating tube for ventilating air sent from the axial fan in the direction of the rotation axis of the axial fan in the direction of the rotation axis, and for blowing the air from the outlet of the ventilation tube to the outside, the ventilation tube An air blower comprising a partition wall that divides the interior into a central part and a peripheral part between the axial fan and the outlet.   The axial fan has a propeller in which a plurality of propeller blades are equally arranged on a peripheral surface of a boss portion, and the partition wall has a length substantially equal to a length between the boss portion and the outlet. The blower according to 1.   The blower according to claim 1 or 2, wherein the ventilation tube and the partition wall are substantially cylindrical.   The blower device according to claim 3, wherein the boss portion has a substantially cylindrical shape, and the partition wall has an outer diameter equal to or larger than a diameter of the boss portion.   The blower according to any one of claims 1 to 4, further comprising an air conditioning body that adjusts a direction of air blown to the outside from the outlet, wherein the partition wall is close to the air conditioning body.   The blower according to any one of claims 3 to 5, wherein the partition wall has a larger diameter on the outlet side than on the axial flow fan side.   An air conditioner comprising: the air blower according to any one of claims 1 to 6; and an ion generation unit that is arranged on the partition wall and generates ions.   An air conditioner comprising: the blower device according to any one of claims 1 to 6; and a medicine discharge section that is disposed on the partition wall and discharges a volatile medicine.   The air conditioner according to claim 7 or 8, wherein the partition wall has a substantially cylindrical shape, and the ion generation unit or the drug discharge unit is disposed in the partition wall.   The partition wall has a hole penetrating in a radial direction from a position facing the ion generation part or the drug discharge part, and the ion generation part or the drug discharge part is exposed in the ventilation tube from the hole. Item 10. An air conditioner according to Item 9.   The air conditioner according to any one of claims 7, 9, and 10, wherein a plurality of the ion generators are arranged separately in a rotation axis direction of the axial fan.

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