JP2011064380A - Air ion supply device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To surely supply air ions of a prescribed concentration or more. <P>SOLUTION: This air ion supply device 1 disposed in a central air supply device 11, having an air ion generator 21 for including negative ions, positive ions or both ions in the air taken from the external of the central air supply device 11, and distributing the air ion generated by the air ion generator 21 to an air ion supply destination through an air duct 31, includes an ion counter 41 disposed in the air duct 31 disposed at the downstream of the air ion generator 21 and detecting the concentration of air ions passing in the air duct 31, and a control means 61 for controlling the generation of air ions by the air ion generator 21 so that the concentration of the air ion detected by the ion counter 41 keeps a prescribed value or more. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an air ion supply device that supplies air ions in which negative ions or positive ions are contained in air to a room such as a house or an office.

  In recent years, it has become difficult to replace indoor air with outdoor air due to high airtightness and high thermal insulation of houses. For this reason, the air supplied to each room is made to contain ions while actively ventilating each room by connecting the ventilation device and each room with a supply air duct and an exhaust air duct. The demand for air ion supply devices is increasing.

  However, the above-described air ion supply apparatus adjusts the amount of air supplied to each room, but does not adjust the concentration of air ions supplied to each room. Therefore, conventionally, an air ion transport system that can arbitrarily adjust the concentration of air ions including negative ions, positive ions, or both ions has been proposed.

  For example, in Patent Document 1, an air ion generator that is provided in a casing of a ventilator and includes negative ions, positive ions, or both ions in air taken from outside, and connected to the casing of the ventilator, An air ion that is composed of an air duct that conveys air to each room and a control device that controls the air ion generator, and supplies air ions having a concentration according to the requirements of each room by controlling the air ion generator A transport system is described.

JP 2005-337611 A

  However, the amount of ions generated by the air ion generator varies under the influence of relative humidity. The generated ions are reduced by the influence of chemical substances. For this reason, in the air ion transport system described in Patent Document 1, there may be a case where a difference occurs between the concentration of air ions required by each room and the concentration of air ions actually supplied from the air ion generator. . As a result, there are cases where the concentration of air ions supplied to each room is less than a predetermined concentration, and the effect of air ions cannot always be obtained in each room.

  In view of the above circumstances, an object of the present invention is to provide an air ion supply device that can reliably supply air ions having a predetermined concentration or more.

  In order to achieve the above object, an air ion supply device according to the present invention is provided in an air supply device, and air that contains negative ions, positive ions, or both ions in the air taken in from the outside of the air supply device. An air ion supply device that has an ion generation device and sends out air ions generated by the air ion generation device to an air ion supply destination via an air duct, and is provided downstream of the air ion generation device. An ion concentration detecting means for detecting the concentration of air ions passing through the air duct, and the air concentration detected by the ion concentration detecting means being equal to or higher than a predetermined value. And a control means for controlling the amount of air ions generated by the ion generator.

  The air ion supply apparatus according to the present invention is characterized in that, in the above invention, the ion concentration detecting means is provided at a downstream end portion of the air duct.

  In the air ion supply device according to the present invention, in the above invention, the control means adjusts an air supply amount by the air supply device to control a wind speed of air passing through the air ion generation device. The air ion concentration is controlled.

  Moreover, the air ion supply device according to the present invention is the air supply device according to the above invention, wherein the air supply device includes a throttle adjustment unit that variably restricts a flow path of the supplied air inside the air supply device, The means is characterized by controlling the speed of air passing through the air ion generator and controlling the concentration of the air ions by controlling the aperture adjustment unit.

  The air ion supply device according to the present invention is the air ion supply device according to the above invention, wherein the air ion generation device includes a plurality of air ion generation means, and the control means turns each air ion generation means on and off to produce the air ions. The density | concentration of is controlled.

  According to the present invention, the ion concentration detection means is arranged in an air duct provided downstream of the air ion generator, detects the concentration of air ions passing through the air duct, and the control means detects the ion The amount of air ions generated by the air ion supply device is controlled so that the concentration of air ions detected by the concentration detection means is equal to or higher than a predetermined value, so that the concentration of air ions at the air ion supply destination can be ensured. Can be maintained at a predetermined value or more.

FIG. 1 is a schematic diagram showing a schematic configuration of an air ion supply apparatus according to an embodiment of the present invention. FIG. 2 is a partially broken perspective view showing the detailed configuration of the air ion generating means. FIG. 3 is a flowchart showing the control processing procedure of the air ion concentration by the control means. FIG. 4 is a schematic diagram illustrating a schematic configuration of a modification of the air ion supply device illustrated in FIG. 1.

  Exemplary embodiments of an air ion supply device according to the present invention will be described below in detail with reference to the accompanying drawings.

  FIG. 1 is a schematic diagram showing a schematic configuration of an air ion supply apparatus according to an embodiment of the present invention. This air ion supply device 1 takes in outside air, generates air ions, sends out air containing the air ions, and each room 81-1 to 81-5 that is a supply destination of air ions. And an air duct 31 that connects between the central air supply device 11 and each of the rooms 81-1 to 81-5, and an ion concentration detection means that is provided in the air duct 31 and detects the concentration of air ions passing therethrough. And a control means 61 for controlling the centralized air supply device 11 so that the ion concentration detected by the ion counter 41 is equal to or higher than a predetermined value. A central monitoring device 51 is connected to the control means 61, and the control means 61 controls at least the ion concentration under the management of the central monitoring device 51.

  The central air supply device 11 forms a box-shaped housing 12 in which the outside air intake port 13 and the air supply port 14 are opened, and the air supply port 14 is provided in the housing 12 from the outside air intake port 13 side. The filter 15, the blower 16, the vane mechanism 17, and the air ion generator 21 are sequentially arranged toward the front.

The filter 15 removes dust, chemical substances, and the like contained in the air taken into the inside from the outside of the central air supply device 11. In the embodiment of the present invention, for example, a filter that removes chemical substances such as NO _x and SO _x decomposed by both positive and negative ions is used.

  The blower 16 is disposed between the filter 15 and the vane mechanism 17, takes air into the inside from the outside air inlet 13 of the central air supply device 11, and takes the taken air from the air inlet 14 to the air duct 31. It will be sent out.

  The vane mechanism 17 is arrange | positioned between the air blower 16 and the air ion generator 21, and squeezes the flow 91 of the air sent from the air blower 16 side variably. For example, the vane mechanism 17 increases the wind speed of the air flow 91 by narrowing down. Here, there is a correlation between the wind speed of the air passing through the air ion generator 21 and the generation amount of air ions, both positive ions and negative ions, and the higher the wind speed, the greater the generation amount of air ions. . Therefore, in this embodiment, the throttle by the vane mechanism 17 is controlled by the control means 61, and thereby the wind speed passing through the air ion generator 21 is controlled. As a result, the amount of air ions generated by the air ion generator 21 is controlled. Will be controlled. The vane mechanism 17 includes a shaft member 17a, an air flow guide member 17b, and a drive unit (not shown). The shaft member 17a is a pair of round bar-like members that are supported by the side walls of the housing 12, and the air flow guide member 17b is a pair of plate-like members that extend to the center of the housing 12, each of which is a shaft member. 17a is supported so as to be swingable about the axis. The vane mechanism 17 restricts the air passage opening area in the housing 12 so as to guide the air flow to the air ion generator 21. A driving unit (not shown) detects the opening state of the vane mechanism 17 according to the driving state, and sends this detection signal to the control means 61.

  The air ion generator 21 has a plurality of air ion generators 21-1 to 21-4. As shown in FIG. 2, the air ion generating means 21-1 has a box shape, and has a front end surface and a rear end surface that are substantially perpendicular to the air flow 91 to form an air passage 21 a through which air flows. An ion generating element 21b that generates air ions is disposed in the ventilation path 21a and in the vicinity of the air inlet 14. The ion generating element 21b generates negative ions, positive ions, or both ions when the air passes, and includes the ions in the passing air.

The ion generating element 21b disposed on the bottom surface side in the ventilation path 21a ionizes oxygen or moisture in the air by applying an alternating high voltage, so that H ⁺ (H ₂ O) m (m is Both positive and negative ions mainly composed of an arbitrary natural number) and O ₂ ⁻ (H ₂ O) _n (n is an arbitrary natural number) are generated. These H ⁺ (H ₂ O) m and O ₂ ⁻ (H ₂ O) _n adhere to the surface of the floating bacteria and chemically react to react with hydrogen peroxide (H ₂ O ₂ ) or a hydroxyl radical as an active species. Inactivate and sterilize planktonic bacteria by producing (.OH). Here, .OH is one kind of active species, and represents radical OH.

  The air duct 31 includes air ducts 31-1 to 31-6, and one air duct 31-1 is connected to the air inlet 14 of the central air supply device 11, and the end of the air duct 31-1 is connected. A plurality of air ducts 31-2 to 31-6 are connected and branched, and the branched air ducts 31-2 to 31-6 are connected to the rooms 81-1 to 81-5 to which air ions are supplied, respectively. Has been. The air duct 31 supplies air ions supplied from the central air supply device 11 to the rooms 81-1 to 81-5, respectively. In this embodiment, the air duct 31 is branched from one air duct 31-1 into a plurality of air ducts 31-2 to 31-6. And the rooms 81-1 to 81-5 may be connected by independent air ducts.

  The ion counter 41 is arranged in the air duct 31 as described above, detects the concentration of air ions flowing through the air duct 31, and sends the detection result to the control means 61. In this embodiment, the ion counter 41 is disposed in the vicinity of the air inlet 14 of the central air supply device 11, but is not limited thereto, and may be in the air duct 31. Here, depending on the air duct 31, air ions may decrease when moving in the air duct 31, so that the air duct is in the air duct 31 and close to the rooms 81-1 to 81-5. It is preferable to provide an ion counter 41 at the end of 31 (see FIG. 4). Further, since both positive and negative ions moving in the air duct 31 tend to attenuate according to the distance of the air duct 31, each room 81-1 is provided as a means for keeping the room at a predetermined ion concentration. It is more preferable to provide the ion counter 41 at the end of the air duct 31 having the longest length of ˜81-5 (see FIG. 4). A plurality of ion counters 41 may be provided in the air duct 31. In this case, the control means 61 may perform control based on the lowest ion concentration among the ion concentrations detected by each ion counter 41, or control using the average value of the ion concentrations detected by each ion counter 41. May be.

  The central monitoring device 51 is connected to the control unit 61 and notifies the control unit 61 of a required ion concentration setting unit 52 that instructs a predetermined value of the air ion concentration, and the abnormality detection content notified from the control unit 61. And a notification unit 53. The required ion concentration setting unit 52 notifies the control means 61 side of a predetermined value of air ion concentration instructed from an input unit (not shown) or the like. In addition, the notification unit 53 notifies the outside of the content of abnormality detection by display output, audio output, or the like.

  Based on the detection result of the ion counter 41, the control means 61 detects an ion concentration control unit 62 that controls the air ion concentration to a predetermined value or higher, and a case where the air ion concentration does not exceed the predetermined value. And an abnormality detection unit 63 that notifies the central monitoring device 51 that the air ion concentration is abnormal. The ion concentration control unit 62 includes a vane control unit 62a, and the vane control unit 62a controls the opening of the vane mechanism 17 so that the air ion concentration becomes a predetermined value or more.

  Here, with reference to the flowchart shown in FIG. 3, the control processing procedure of the air ion concentration by the control means 61 is demonstrated. In FIG. 3, first, the ion concentration control unit 62 acquires the air ion concentration detected by the ion counter 41 (step S101). Thereafter, the ion concentration control unit 62 determines whether or not the acquired air ion concentration is less than a predetermined value (step S102). This predetermined value is set in advance by an instruction from the required ion concentration setting unit 52 of the central monitoring device 51 as described above. When the air ion concentration is less than the predetermined value (step S102, Yes), the ion concentration control unit 62 determines whether or not the opening by the vane mechanism 17 is minimum (step S103). When the opening by the vane mechanism 17 is not minimum (step S103, No), the ion concentration control part 62 narrows the opening by the vane mechanism 17 (step S104). By narrowing the opening, the wind speed passing through the air ion generator 21 increases, and the increase in the wind speed increases the amount of air ions generated. Then, it transfers to step S101 and repeats the process mentioned above.

  On the other hand, when the air ion concentration is not less than the predetermined value (step S102, No), the control unit 61 moves the process to step S101 and repeats the above-described process. By the processing from step S101 to step S104, the air ion concentration in each of the rooms 81-1 to 81-5, which is the air ion supply destination, can be maintained at a predetermined value or more.

  In addition, when the opening by the vane mechanism 17 is the minimum (step S103, Yes), the air ion concentration cannot be set to a predetermined value or more, and the ion concentration control unit 62 has an abnormality in the control of the air ion concentration. Therefore, the central monitoring device 51 is notified of the abnormality (step S105). Thereafter, the control means 61 ends this process.

  In this embodiment, an ion counter 41 is disposed in the air duct 31 and extends from the air ion generation device 21 that is a generation source of air ions to the rooms 81-1 to 81-5 that are supply destinations of air ions. Since the air ion concentration is detected by the ion counter 41, the control means 61 controls the air ion concentration to be equal to or higher than a predetermined value based on the air ion concentration detected by the ion counter 41. The air ion concentration in each of the rooms 81-1 to 81-5 can be maintained at a predetermined value or higher.

Further, since the filter 15 for removing chemical substances such as NO _x and SO _x is provided, these chemical substances are required until the air ions are transferred to the respective rooms 81-1 to 81-5 as the supply destination. It is possible to prevent a situation in which the concentration of air ions decreases due to the influence of.

  Furthermore, when control is not possible to exceed the air ion concentration of a predetermined value required by each of the rooms 81-1 to 81-5 to which the air ions are supplied, an abnormality is detected and notified. It becomes possible to quickly cope with a decrease in the concentration of air ions due to the influence of chemical substances that could not be removed, malfunctions of the air ion generation device 21, and the like.

  In the above-described embodiment, the control means 61 controls the opening of the vane mechanism 17, but not limited thereto, as shown in FIG. 4, each air ion generation means of the air ion generation device 21. The amount of generated air ions may be directly controlled by controlling on / off of 21-1 to 21-4. Moreover, the control means 61 may control the air blower 16 to directly control the air flow rate, and the air ion generation amount may be controlled by controlling the wind speed passing through the air ion generator 21. Further, the control means 61 may control the vane mechanism 17, the air ion generation device 21, and the blower 16 by appropriately combining them.

  In the above-described embodiment, the air ion generation device 21 is described on the assumption that an air ion generation device that generates both positive and negative ions is used. However, the present invention is not limited to this. For example, only negative ions or positive ions are used. You may use the air ion generator which generate | occur | produces.

DESCRIPTION OF SYMBOLS 1, 2 Air ion supply apparatus 11 Centralized air supply apparatus 12 Case 13 Outside air intake port 14 Air supply port 15 Filter 16 Blower 17 Vane mechanism 17a Shaft member 17b Air flow guide member 21 Air ion generator 21-1-21- 4 Air ion generation means 21a Ventilation path 21b Ion generation element 31, 31-1 to 31-6 Air duct 41 Ion counter 51 Central monitoring device 52 Required ion concentration setting unit 53 Notification unit 61 Control unit 62 Ion concentration control unit 62a Vane control Unit 63 Abnormality notification unit 81, 81-1 to 81-5 Room

Claims (5)

An air ion generator provided in the air supply device and including negative ions, positive ions, or both ions in the air taken from the outside of the air supply device, and the air ions generated by the air ion generator, An air ion supply device that sends air ions to a destination via an air duct,
An ion concentration detection means that is disposed in an air duct provided downstream of the air ion generator and detects the concentration of air ions passing through the air duct;
Control means for controlling the amount of air ions generated by the air ion generator so that the concentration of air ions detected by the ion concentration detection means is not less than a predetermined value;
An air ion supply device comprising:   The air ion supply apparatus according to claim 1, wherein the ion concentration detection means is provided at a downstream end portion of the air duct.   The said control means controls the density | concentration of the said air ion by adjusting the air supply amount by the said air supply apparatus, and controlling the wind speed of the air which passes through the said air ion generator, The said control means is characterized by the above-mentioned. 2. The air ion supply device according to 2. The air supply device includes, in the air supply device, a throttle adjustment unit that variably restricts the flow path of the supplied air,
The said control means controls the wind speed of the air which passes the said air ion generator by controlling the said aperture adjustment part, and controls the density | concentration of the said air ion. The air ion supply apparatus as described in any one. The air ion generation device includes a plurality of air ion generation means,
5. The air ion supply device according to claim 1, wherein the control unit controls each air ion concentration by turning on and off each air ion generation unit.

Images