JP6026178B2 - air conditioner - Google Patents

Description

  The present invention relates to an air conditioner, and more particularly to an air conditioner including a charged particle generation device.

  Japanese Unexamined Patent Publication No. 2011-098074 (Patent Document 1) discloses an invention related to an air cleaner. This air purifier includes a charged particle generating device that generates charged particles. The publication states that according to this air cleaner, electrostatic mist can be stably supplied without being affected by the main airflow.

JP 2011-098074 A

  An object of the present invention is to provide an air conditioner that includes two charged particle generation devices, each of which can generate charged particles with high generation efficiency.

An air conditioner according to an aspect of the present invention includes a housing including an accommodating portion, a ventilation path, and an air outlet provided at a downstream position of the ventilation path, and a first charged particle generation device disposed in the casing. And a first ventilation means disposed in the housing and for sending charged particles generated by the first charged particle generator from the outlet to the outside of the housing, and detachably attached to the housing portion, A second charged particle generation device including two ventilation means, wherein the second charged particle generation device includes a power source, a high voltage circuit that generates a high voltage from a voltage supplied from the power source, and the high voltage circuit. A charged particle generating unit that generates charged particles upon receiving the high voltage from the second charged particle generating device, wherein the second charged particle generating device is attached to the housing unit. Using the second ventilation means Serial capture a portion of the airflow from the first air means, by generating charged particles exiting the feed to the outside of the casing together with the part of the air flow, the said housing part, attached to the housing part A conductive member that is in electrical contact with the second charged particle generating device is provided, and the electric charge charged in the second charged particle generating device is released through the conductive member.
An air conditioner according to another aspect of the present invention includes a housing including an accommodating portion, a ventilation path, and a blowout port provided at a downstream position of the ventilation path, and first charged particle generation disposed in the casing. An apparatus, a first ventilation means that is disposed in the casing and that sends out the charged particles generated by the first charged particle generation apparatus from the outlet to the outside of the casing, and is detachably attached to the housing portion, A second charged particle generation device including a second ventilation means, wherein the second charged particle generation device includes a power source, a high voltage circuit that generates a high voltage from a voltage supplied from the power source, and the high voltage. A charged particle generating unit that receives the high voltage from the circuit to generate charged particles, and in a state where the second charged particle generating device is attached to the housing unit, the second charged particle generating device Using the second ventilation means Taking in part of the airflow from the first ventilation means, generating charged particles, sending them out together with the part of the airflow to the outside of the housing, and sending out a control signal for controlling the second charged particle generating device A control unit; and a plurality of connection terminals provided in a convex shape inside the housing unit, wherein the second charged particle generating device attached to the housing unit transmits the control signal through the connection terminal. Receive.

  Preferably, a guide portion that guides the part of the airflow from the first ventilation means to the second ventilation means of the second charged particle generating device attached to the housing portion is provided in the ventilation path. Provided.

  Preferably, the housing includes a first surface member for forming the ventilation path and a second surface member facing the first surface member, and the first charged particle generation device is connected to the ventilation path. The second charged particle generating device is disposed on the second surface member side as viewed from the ventilation path.

  Preferably, the first charged particle generation device is located on the upstream side of the ventilation path with respect to the guide portion.

  Preferably, the first charged particle generating device is located on the downstream side of the ventilation path with respect to the guide portion.

  Preferably, the power supply unit further supplies power to the second charged particle generation device, and the second charged particle generation device attached to the housing unit is charged by receiving the power through the connection terminal.

  Preferably, when a virtual equilateral triangle is drawn, three of the plurality of connection terminals are arranged one by one at three vertices of the equilateral triangle, and the other three of the plurality of connection terminals Are arranged one by one on the three sides of the equilateral triangle.

  According to the present invention, it is possible to obtain an air conditioner in which two charged particle generators can generate charged particles with high generation efficiency.

It is a perspective view which shows the air conditioner in Embodiment 1. FIG. 2 is a top view showing the air conditioner in Embodiment 1. FIG. It is a front view which shows the air conditioner in Embodiment 1. It is a right view which shows the air conditioner in Embodiment 1. It is arrow sectional drawing along the VV line in FIG. It is sectional drawing which shows the air conditioner in Embodiment 1. It is a figure which shows the operation panel used for the air conditioner in Embodiment 1. FIG. It is a perspective view which shows the assembled state of the charged particle production | generation apparatus 2 used for the air conditioner in Embodiment 1. FIG. It is a perspective view which shows the state which the charged particle production | generation apparatus 2 used for the air conditioner in Embodiment 1 decomposed | disassembled. 3 is a perspective view showing a charged particle generating element of the charged particle generating device 2 used in the air conditioner according to Embodiment 1. FIG. It is a figure which shows the functional block of the air conditioner in Embodiment 1. FIG. FIG. 3 is a cross-sectional view showing the operation of the air conditioner in the first embodiment. It is sectional drawing which shows the air conditioner in Embodiment 2. It is sectional drawing which shows the air conditioner in Embodiment 3. It is a rear view which shows 2A of charged particle generators used for the air conditioner in Embodiment 4. FIG. It is a side view which shows 2A of charged particle production | generation apparatuses used for the air conditioner in Embodiment 4. It is a figure which shows the accommodating part with which the air conditioner in Embodiment 4 is provided. It is a figure which shows the 1st modification of the charged particle production | generation apparatus used for the air conditioner in Embodiment 4. FIG. It is a figure which shows the 2nd modification of the charged particle production | generation apparatus used for the air conditioner in Embodiment 4. FIG. It is a figure which shows the 3rd modification of the charged particle production | generation apparatus used for the air conditioner in Embodiment 4. FIG. It is a figure which shows a mode that the charged particle production | generation apparatus used for the air conditioner in Embodiment 5 is accommodated in an apparatus main body. It is a bottom view which shows the connector seen from the bottom part of the case of the charged particle generation apparatus used for the air conditioner in Embodiment 5. It is a figure which shows typically the cross section of the case of the charged particle production | generation apparatus used for the air conditioner in Embodiment 5. FIG. It is a bottom view which shows the connector seen from the bottom part of the case of the charged particle generation apparatus used for the air conditioner in the modification of Embodiment 5. It is a figure which shows typically the cross section of the case of the charged particle production | generation apparatus used for the air conditioner in the modification of Embodiment 5. FIG.

  Embodiments based on the present invention will be described below with reference to the drawings. In the description of each embodiment, when referring to the number, amount, and the like, the scope of the present invention is not necessarily limited to the number, the amount, and the like unless otherwise specified. In the description of each embodiment, the same parts and corresponding parts are denoted by the same reference numerals, and redundant description may not be repeated.

[Embodiment 1]
(External configuration of the air conditioner 11)
With reference to FIGS. 1-12, the air conditioner 11 in this Embodiment is demonstrated. FIG. 1 is a perspective view showing an air conditioner 11. FIG. 2 is a top view showing the air conditioner 11. FIG. 3 is a front view showing the air conditioner 11. FIG. 4 is a right side view showing the air conditioner 11.

  As shown in FIGS. 1 to 4, the air conditioner 11 includes a device main body 1 and a charged particle generation device 2. The device main body 1 includes a housing 100, an operation panel 104, a wind direction adjusting unit 106, a water supply tank 108, and a water receiving unit 110. The operation panel 104 and the wind direction adjusting unit 106 are provided on the upper surface side of the housing 100. The water supply tank 108 and the water receiving unit 110 are provided on the back side of the housing 100.

  An intake port 112 and a power cord connection port 114 are provided on the right side surface of the housing 100 (see FIGS. 1 and 4). An intake port (not shown) similar to the intake port 112 is also provided on the left side surface of the housing 100. An air inlet 112 located on the right side of the housing 100 and an air inlet (not shown) located on the left side of the housing 100 communicate with the ventilation path 121 (see FIG. 5) inside the housing 100. . A power cord (not shown) is connected to the power cord connection port 114.

(Internal configuration of air conditioner 11)
FIG. 5 is a cross-sectional view taken along the line VV in FIG. When the air conditioner 11 is used, the casing 100 is placed on a floor surface, for example. The housing 100 includes a housing portion 102, ventilation paths 121 to 123, and an air outlet 124. In the housing 100, a filter 126, a blower 128 (first ventilation means), a charged particle generation device 130 (first charged particle generation device), a control circuit 132 (control unit), and a charged particle generation device 2 (second second). A charged particle generator) is arranged.

  Air is supplied to the ventilation path 121 through an intake port 112 (see FIG. 1) provided on the right side surface of the housing 100 and an intake port (not shown) provided on the left side surface of the housing 100. The ventilation path 121 communicates with the ventilation path 122. The ventilation path 122 communicates with the ventilation path 123. The air outlet 124 is provided at a downstream position of the ventilation path 123. The accommodating part 102 is located in the vicinity of the blower outlet 124 and the wind direction adjusting part 106.

  As indicated by an arrow AR1 in FIG. 6, the charged particle generation device 2 (second charged particle generation device) is detachably attached to the storage unit 102. In FIG. 5, a state in which the charged particle generating device 2 is attached to the housing portion 102 is shown. In FIG. 6, a state in which the charged particle generating device 2 is removed from the housing portion 102 is shown. Details of the charged particle generation device 2 will be described later with reference to FIGS.

  The operation panel 104 is disposed on the upper surface side of the housing 100. The operation panel 104 is operated by a user and receives a user instruction. In a state where the charged particle generation device 2 is attached to the housing portion 102 of the device main body 1, the operation panel 104 functions as an overall operation panel of the air conditioner 11. On the other hand, the operation panel 104 functions as an operation panel of the device main body 1 in a state where the charged particle generation device 2 is detached from the device main body 1. Further details of the operation panel 104 will be described later with reference to FIG.

  The wind direction adjusting unit 106 is also arranged on the upper surface side of the housing 100. The wind direction adjusting unit 106 is rotatable about the support unit 106P (see FIGS. 5 and 6). As the wind direction adjusting unit 106 rotates, the air outlet 124 is opened and closed. An air path forming unit 106T is provided on the opposite side of the air direction adjusting unit 106 with the support unit 106P interposed therebetween. The air passage forming unit 106T is located on the air passage 123 side when viewed from the air direction adjusting unit 106.

  The air direction adjusting unit 106 and the air path forming unit 106T each have a plate shape, and the size of the air path forming unit 106T is smaller than the size of the air direction adjusting unit 106. The air direction adjusting unit 106 and the air path forming unit 106T rotate integrally around the support unit 106P. The air blowing direction from the air outlet 124 of the device main body 1 is defined according to the inclination of the air direction adjusting unit 106 and the air path forming unit 106T.

  The water supply tank 108 stores water 119. The water receiver 110 is disposed below the water supply tank 108. The water receiver 110 supports the water supply tank 108 and receives water 119 from the water supply tank 108. In the present embodiment, the water supply tank 108 can be attached to and detached from the housing 100. The water supply tank 108 may be integrated with the housing 100. The water supply tank 108 may be provided as necessary.

  The filter 126 is disposed between the ventilation path 121 and the ventilation path 122. The lower part of the filter 126 is immersed in the water 119 supplied to the water receiver 110. The blower 128 is disposed between the ventilation path 122 and the ventilation path 123. The blower 128 is, for example, a sirocco fan. The air flowing through the ventilation path 121 by the operation of the blower 128 passes through the filter 126. When the air passes through the filter 126, dust or the like is removed from the air, and the air is humidified. The air that has passed through the filter 126 passes through the ventilation path 122 and is sent to the ventilation path 123 by the blower 128.

(Charged particle generator 130)
The charged particle generator 130 is disposed in the middle of the ventilation path 123. In the present embodiment, case 100 has first surface member 123A (see FIG. 6) and second surface member 123B (see FIG. 6) facing first surface member 123A. The first surface member 123 </ b> A and the second surface member 123 </ b> B form a ventilation path 123.

  As described above, the housing 100 is provided with the housing portion 102 for housing the charged particle generating device 2. A guide portion 125 is provided at a height position substantially the same as that of the charged particle generation device 130 in the ventilation path 123. The guide part 125 is comprised from the plate-shaped member, and has cross-sectional view substantially L-shape. The accommodating portion 102 is formed between the guide portion 125 and the second surface member 123B. The upstream portion of the guide portion 125 is bent toward the blower 128 in the air flow direction in the ventilation path 123.

  The charged particle generation device 130 is disposed on the first surface member 123 </ b> A side when viewed from the ventilation path 123. The container 102 and the charged particle generation device 2 are disposed on the second surface member 123B side as viewed from the ventilation path 123. The air flowing in the ventilation path 123 starts from the tip end portion 125T located on the most upstream side of the guide portion 125, and flows to the charged particle generation device 130 side, and flows to the storage portion 102 (charged particle generation device 2) side. Branch to one. The charged particle generation device 130 of the present embodiment is located on the downstream side (near the air outlet 124) of the ventilation path 123 with respect to the front end portion 125 </ b> T of the guide portion 125 in the direction of the airflow generated by the blower 128.

  The charged particle generation device 130 includes an ion generation electrode (not shown) and a counter electrode disposed to face the ion generation electrode, and generates charged particles by corona discharge. In the present embodiment, the charged particles include both positive ions and negative ions. The charged particle generation device 130 may generate only one of positive ions and negative ions.

The positive ions are combined with moisture contained in the air passing through the ventilation path 123. The positive ions mainly contain H ⁺ (H ₂ O) m (m is an arbitrary natural number), and form positively charged cluster ions. Negative ions also bind to moisture contained in the air passing through the ventilation path 123. The negative ions mainly include O ₂ ⁻ (H ₂ O) n (n is zero or any natural number), and form cluster ions having a negative charge. Positive ions and negative ions float in the air passing through the ventilation path 123.

  As described above, the charged particle generating device 2 can be attached to and detached from the device main body 1 (see arrow AR1). Although details will be described later, the charged particle generation device 2 includes a clip 250. In a state where the charged particle generating device 2 is disposed in the housing portion 102, the charged particle generating device 2 is placed in the housing portion 102 by utilizing friction (friction engagement) generated between the clip 250 and the guide portion 125. Fixed.

  A connector 131 is disposed on the bottom surface 103 of the housing portion 102. The connector 131 includes a plurality of connection terminals that are electrically connected to the charged particle generation device 2 attached to the housing unit 102. The connector 131 (a plurality of connection terminals) is provided in a convex shape so as to protrude from the surface of the housing portion 102 inside the housing portion 102. The connector 131 may be disposed on the side surface 101 (second surface member 123B) of the housing portion 102.

  The control circuit 132 is electrically connected to the connector 131. In a state where the charged particle generating device 2 is attached to the housing portion 102 of the device main body 1, the control circuit 132 and the charged particle generating device 2 are electrically connected through the connector 131. The control circuit 132 controls the device main body 1, the charged particle generation device 2, and the like. When the operation panel 104 is operated by the user, a signal indicating the operation content is sent to the control circuit 132. The control circuit 132 controls the device main body 1 and the charged particle generating device 2 in response to the signal.

  In a state where the charged particle generating device 2 is attached to the housing portion 102 of the device main body 1, the control circuit 132 controls the charged particle generating device 2 together with the device main body 1, and the charged particle generating device 2 is interlocked with the device main body 1. To do. The charged particle generating device 2 also generates an air flow including charged particles. Not only the device body 1 but also the charged particle generator 2 can generate charged particles from the air conditioner 11 by generating charged particles.

(Operation panel 104)
FIG. 7 is a diagram showing an operation panel 104 used in the air conditioner 11 (see FIG. 1). The operation panel 104 is provided with operation buttons 151 to 154 and display lamps 155 to 163. Each of the operation buttons 151 to 154 is operated by a user. A signal corresponding to the operation is sent to the control circuit 132 (see FIG. 6). The display lamps 155 to 163 notify the user of predetermined information.

  The operation button 151 is a button for the user to instruct the air conditioner 11 to start and stop the air conditioner 11. When the operation of the air conditioner 11 is instructed, the display lamp 155 is turned on. When the stop of the air conditioner 11 is instructed, the display lamp 155 is turned off. The operation button 152 is a button for the user to instruct the air volume of the air conditioner 11 to the air conditioner 11. The air conditioner 11 includes an automatic mode and a manual mode as modes relating to air volume setting. By the operation of the operation button 152, the automatic mode and the manual mode are switched alternately.

  When the automatic mode is selected, the display lamp 156 is turned on. In the manual mode, the air volume is switched between three levels of “strong”, “medium” and “silent”. The display lamps 157 to 159 correspond to “strong”, “medium”, and “silent”, respectively. When one of the “strong”, “medium”, and “silent” stages is selected, the corresponding display lamp among the display lamps 157 to 159 is turned on.

  The operation button 153 is a button for the user to operate in order to switch whether or not to generate ions from the air conditioner 11. When ion generation from the air conditioner 11 is selected, the display lamp 160 is turned on. The operation button 154 is a button for the user to set a timer operation. When the operation button 154 is operated during the operation of the air conditioner 11, the air conditioner 11 stops after a certain time from the time of the operation. When the timer operation is selected, the display lamp 161 is turned on.

  The display lamp 162 is a lamp for indicating that it is time to replace the charged particle generation device 130. The total operation time (cumulative usage time) of the device body 1 is measured by the control circuit 132 (see FIG. 6). When the accumulated usage time of the device body 1 reaches a specified time, the display lamp 162 blinks. This specified time is determined in advance in consideration of the reduction rate of the generation amount of the charged particles with respect to the usage time of the charged particle generation device 130.

  The display lamp 163 indicates that the air conditioner 11 is humidifying the air. When the air conditioner 11 is not humidifying the air, the display lamp 163 is turned off. When the air conditioner 11 is humidifying the air, the display lamp 163 is lit in green. When the water supply tank 108 (see FIG. 1) of the device main body 1 needs to be supplied with water, the display lamp 163 blinks red.

(Charged particle generator 2)
FIG. 8 is a perspective view showing an assembled state of the charged particle generation device 2. FIG. 10 is a perspective view showing an exploded state of the charged particle generation device 2. With reference to FIGS. 9 and 10, the charged particle generation device 2 includes a case 201, a blower fan 203 (second ventilation unit), a battery 207 (power supply), a switch 208, a connector 209, a substrate 211, and a charged particle generation element 220. And a clip 250. The clip 250 is provided on the outer surface of the case 201. Using the clip 250, the charged particle generating device 2 can be easily attached to a user's clothes or the like.

  The case 201 has a side surface 201 c perpendicular to the width direction (Y direction) of the case 201. A suction port 230 for introducing external air into the case 201 is formed on the side surface 201c. In a state in which the charged particle generating device 2 is attached to the housing portion 102 (see FIG. 6) of the device main body 1, a part of the airflow passing through the ventilation path 123 (see FIG. 6) enters the case 201 through the suction port 230. It is captured.

  A blower outlet 240 is formed at one end 201d in the longitudinal direction (X direction) of the case 201 to blow out the air in the case 201 to the outside. Inside the case 201, an air passage that connects the suction port 230 and the air outlet 240 is formed. In a state in which the charged particle generating device 2 is attached to the housing portion 102 (see FIG. 6) of the device main body 1, the air blown out from the blower outlet 240 is exposed to the outside through the blower outlet 124 (see FIG. 6) of the device main body 1. Blown out.

  As shown in FIG. 9, the case 201 includes an upper case 201a and a lower case 201b. The upper case 201a and the lower case 201b are integrated to form a thin box-like case 201. In the case 201, a blower fan 203, a battery 207, a switch 208, a connector 209, and a charged particle generating element 220 are accommodated.

  The blower fan 203 is a centrifugal fan or a propeller fan. The blower fan 203 operates using power supplied from the battery 207 or power supplied from the device main body 1 through the connector 209. Due to the operation of the blower fan 203, part of the external air or airflow passing through the ventilation path 123 (see FIG. 6) is introduced into the case 201 from the suction port 230 and blown out from the blower outlet 240 to the outside. .

  The blower fan 203 is disposed between the surface 211a of the substrate 211 and the inner surface of the upper case 201a. The blower fan 203 has an opening 203a and an opening 203b. The opening 203 a is formed on the surface of the blower fan 203 that is perpendicular to the thickness direction (Z direction) of the blower fan 203. The opening 203b is formed on the surface of the blower fan 203 located on the same side as the air outlet 240.

  The battery 207 is a direct current power source and a power storage device that stores electric power. The battery 207 includes a secondary battery such as a nickel metal hydride battery or a lithium ion battery. The battery 207 supplies DC power to the blower fan 203 and the charged particle generation element 220. In a state where the charged particle generation device 2 is attached to the housing portion 102 of the device main body 1, the battery 207 receives DC power from the device main body 1 through the connector 209 and the connector 131 (see FIG. 6). The battery 207 is charged with this electric power. The voltage of the battery 207 is about several volts.

  The battery 207 is disposed at a position that does not hinder the airflow generated by the operation of the blower fan 203. In the configuration shown in FIG. 9, the battery 207 is disposed so as to overlap the blower fan 203 along the Z direction. The switch 208 receives a user operation. The user can switch between operation and stop of the charged particle generation device 2 by operating the switch 208.

  The connector 209 includes a plurality of connection terminals. The plurality of connection terminals include a power supply terminal and a signal input terminal. The power supply terminal is a terminal for receiving DC power from the device main body 1. The electric power input from the device main body 1 through the power supply terminal is supplied to the blower fan 203, the charged particle generating element 220 and the battery 207. The signal input terminal receives various control signals from the control circuit 132 (control unit) of the device body 1. The charged particle generation device 2 operates in response to a control signal input from the signal input terminal of the connector 209.

  FIG. 10 is a perspective view showing the charged particle generating element 220. Referring to FIGS. 9 and 10, charged particle generation element 220 includes a substrate 211, a drive unit 210 (high voltage circuit), and a charged particle generation unit 215. The drive unit 210 is disposed on the surface 211 a of the substrate 211. The drive unit 210 is for controlling the discharge in the charged particle generation unit 215, and includes a pulse generation circuit, a capacitor, an FET (Field Effect Transistor), and the like.

  The drive unit 210 is connected to the battery 207 and the charged particle generation unit 215. The drive unit 210 boosts the voltage from the battery 207 to 10V to 20V and outputs it to the charged particle generation unit 215. The driving unit 210 generates a pulse signal for discharge control of the charged particle generation unit 215 and outputs the signal to the charged particle generation unit 215.

  The charged particle generation unit 215 includes a high voltage generation unit 206, a positive rectification element 205a, a negative rectification element 205b, a positive ion discharge unit 204a, and a negative ion discharge unit 204b. The high voltage generation unit 206 includes a transformer and generates positive and negative high voltages of 2 kV to 10 kV in response to the signal input from the driving unit 210.

  Positive rectifying element 205a and negative rectifying element 205b include, for example, a diode. The positive-side rectifying element 205a and the negative-side rectifying element 205b have, for example, a cylindrical shape and are configured to be energized in the longitudinal direction. The positive-side rectifying element 205a and the negative-side rectifying element 205b are arranged so that the energization direction is parallel to the Y direction. The positive rectifying element 205 a and the negative rectifying element 205 b are arranged so as to be embedded in the thickness direction of the substrate 211 from the surface 211 a of the substrate 211.

  Positive rectifier element 205a is connected to high voltage generator 206 and positive ion discharger 204a. Positive side rectifying element 205a passes only a positive high voltage among positive and negative high voltages generated by high voltage generation unit 206 to positive ion discharge unit 204a. The negative side rectifying element 205b is connected to the high voltage generation unit 206 and the negative ion discharge unit 204b. The negative rectifying element 205b allows only the negative high voltage among the positive and negative high voltages generated by the high voltage generation unit 206 to pass to the negative ion discharge unit 204b.

  The positive ion discharge part 204a and the negative ion discharge part 204b are parts for generating ions by discharge, and have a needle shape with a sharp tip. The positive ion discharge part 204a and the negative ion discharge part 204b are metals having high heat resistance and high corrosion resistance, and are made of, for example, Inconel. One end (tip) of the needle shape of the positive ion discharge part 204a is exposed to the air, and the other end of the positive ion discharge part 204a is connected to the positive side rectifying element 205a. One end (tip) of the needle shape of the negative ion discharge portion 204b is exposed to the air, and the other end of the negative ion discharge portion 204b is connected to the negative side rectifying element 205b. The negative ion discharge part 204b is provided away from the positive ion discharge part 204a in the Y direction.

(Function block of air conditioner 11)
FIG. 11 is a diagram illustrating functional blocks of the air conditioner 11. The apparatus main body 1 includes a power cord connection port 114, a power supply unit 140, a charged particle generation device 130, a blower 128, a wind direction adjustment unit 106, a control circuit 132, an operation panel 104, and a connector 131 as functional blocks. For convenience, the connector 131 is shown separately from the control circuit 132 in FIG.

  The power supply unit 140 receives power through the power cord 115 connected to the power cord connection port 114. The power supply unit 140 supplies power to the charged particle generation device 130, the blower 128, the wind direction adjustment unit 106, the control circuit 132, and the operation panel 104. In a state where the charged particle generation device 2 is attached to the housing unit 102 of the device main body 1, the power supply unit 140 supplies power to the charged particle generation device 2 through the connector 131.

  The operation panel 104 uses the power from the power supply unit 140 to turn on the display lamp and generate a signal corresponding to the user's operation. Control circuit 132 receives a signal from operation panel 104. The control circuit 132 controls the charged particle generation device 130, the blower 128, and the wind direction adjusting unit 106 in response to the signal. In a state where the charged particle generation device 2 is attached to the housing portion 102 of the device main body 1, the control circuit 132 transmits a control signal to the charged particle generation device 2 through the connector 131.

  The control circuit 132 controls the charged particle generator 130 to generate positive ions and negative ions from the charged particle generator 130. The control circuit 132 controls the blower 128 to control the air volume from the device main body 1. The air conditioner 11 may further include various sensors such as a dust sensor. The control circuit 132 can determine the air volume based on the detection result of the sensor, and can control the blower 128 so that the air volume is achieved. The control circuit 132 controls the wind direction adjusting unit 106 to control the direction of the wind sent from the device main body 1 and the charged particle generating device 2.

  The charged particle generation device 2 includes a battery 207, a switch 208, a charged particle generation element 220, a blower fan 203, a control circuit 260, a connector 209, and a charging circuit 280. The charging circuit 280 may be provided as necessary. The switch 208 is operated by the user. When the charged particle generating device 2 is used in a state where it is detached from the housing unit 102, the battery 207 applies a voltage to the charged particle generating element 220 and controls the blower fan 203 and the control by turning on the switch 208. Power is supplied to the circuit 260.

  The switch 208 may accept a user instruction regarding air volume switching. The switch 208 may accept a user instruction for switching the air volume between at least two stages such as “weak” and “strong”. In the case of this configuration, the control circuit 260 detects the state of the switch 208. The control circuit 260 controls the blower fan 203 so that the air volume is switched stepwise according to the state of the switch 208.

  When the charged particle generation device 2 is used in a state where it is detached from the storage unit 102, the control circuit 260 is activated by supplying power from the battery 207. When the control circuit 260 is activated, the control circuit 260 activates the drive unit 210 and the blower fan 203. An air stream containing charged particles is generated from the charged particle generator 2.

  In a state where the charged particle generation device 2 is attached to the housing portion 102 of the device main body 1, the connector 209 is connected to the connector 131. The charged particle generator 2 receives power and control signals from the device body 1. The connector 209 has a power supply terminal 291 and a signal input terminal 292. The power terminal 291 receives power from the device body 1. The power supply terminal 291 is electrically connected to the battery 207 through the charging circuit 280. The power supply terminal 291 is electrically connected to the control circuit 260 and the charged particle generating element 220.

  The signal input terminal 292 is electrically connected to the control circuit 260. The control circuit 260 receives a control signal from the device main body 1 through the signal input terminal 292. The electric power from the device body 1 is supplied to the control circuit 260, the charged particle generating element 220 and the blower fan 203. The control circuit 260 activates and stops both the charged particle generating element 220 and the blower fan 203 in accordance with a control signal from the device main body 1.

  The electric power from the device main body 1 is further supplied to the battery 207 through the charging circuit 280. For example, the control circuit 260 operates the charging circuit 280 to charge the battery 207 in a state where the device main body 1 stops blowing air. The control circuit 260 may operate the charging circuit 280 to charge the battery 207 in a state where both the device main body 1 and the charged particle generation device 2 are operating.

  In a state in which the charged particle generating device 2 is attached to the housing portion 102 of the device main body 1, the charged particle generating device 2 works with the device main body 1. The state where the charged particle generation device 2 is attached to the housing portion 102 of the device main body 1 is a state where the connector 131 of the device main body 1 and the connector 209 of the charged particle generation device 2 are electrically connected. In this state, when the operation of the device main body 1 starts, the charged particle generation device 2 operates. On the other hand, when the device main body 1 stops, the charged particle generation device 2 also stops.

  “Interlocking” includes that the start and end of the operation of the charged particle generation device 2 are triggered by the start and end of the operation of the device body 1, respectively. It is not necessary that the operation and stop timing of the charged particle generating device 2 coincide with the operation and stop timing of the device main body 1. For example, the charged particle generation device 2 may start operating after the start of the operation of the device body 1. For example, the charged particle generation device 2 may stop after the device main body 1 stops.

(Operation of air conditioner 11)
With reference to FIG. 12, operation | movement of the air conditioning machine 11 comprised as mentioned above is demonstrated. It is assumed that the air conditioner 11 is driven by the user in a state where the charged particle generation device 2 is attached to the housing unit 102. The control circuit 132 operates the wind direction adjusting unit 106 in accordance with a signal from the operation panel 104 to open the air outlet 124.

  The control circuit 132 controls the charged particle generator 130 and the charged particle generator 2 to generate charged particles. Air is taken into the housing 100 (ventilation path 121) by the operation of the blower 128. The white arrow in the figure represents the airflow. The air is humidified as necessary, and is sent to the ventilation path 123 through the ventilation path 122. The airflow passing through the ventilation path 123 sends charged particles generated by the charged particle generation device 130 out of the housing 100 from the outlet 124.

  A part of the airflow passing through the ventilation path 123 flows to the accommodating portion 102 side by the guide portion 125. The airflow that has flowed to the housing portion 102 side is taken into the charged particle generating device 2 through the suction port 230 (see FIG. 9), and the charged particles generated by the charged particle generating device 2 are transferred from the outlet 124 to the outside of the housing 100. To send. Under the present circumstances, the airflow more than the function of the ventilation fan 203 (refer FIG. 9) with which the charged particle generator 2 is provided is supplied in the charged particle generator 2 in response to the ventilation from the blower 128. The amount of airflow taken into the charged particle generation device 2 is such that the charged particle generation device 2 is attached to the storage unit 102 as compared to the case where the charged particle generation device 2 is removed from the storage unit 102 and used alone. More cases.

  The amount of charged particles generated from the charged particle generating device 2 is proportional to the amount of airflow supplied to the charged particle generating device 2. The amount of charged particles generated from the charged particle generation device 2 is larger than that when the charged particle generation device 2 is removed from the storage unit 102 and used alone, compared to the case where the charged particle generation device 2 is attached to the storage unit 102. If there are more. Therefore, according to the air conditioner 11, the charged particle generation device 130 and the charged particle generation device 2 can generate charged particles with high generation efficiency.

  As described above, the guide portion 125 is provided in the ventilation path 123 of the air conditioner 11. By providing the guide portion 125, a part of the airflow passing through the ventilation path 123 is actively guided toward the suction port 230 (see FIG. 9) of the charged particle generation device 2. By providing the guide portion 125, the amount of charged particles generated from the charged particle generating device 2 can be further increased. The guide part 125 may be provided as necessary.

  As described above, the charged particle generation device 130 is disposed on the first surface member 123 </ b> A side as viewed from the ventilation path 123. The container 102 and the charged particle generation device 2 are disposed on the second surface member 123B side as viewed from the ventilation path 123. The first surface member 123A and the second surface member 123B are disposed to face each other. When air containing charged particles is blown out from the air outlet 124, the air to which charged particles are added by the charged particle generating device 130 flows through a portion of the ventilation path 123 near the first surface member 123 </ b> A, and the charged particle generating device 2. The air to which the charged particles are added flows through the portion of the ventilation path 123 near the second surface member 123B.

  The air to which the charged particles are added by the charged particle generator 130 is blown out from the outlet 124 as indicated by the arrow DR1. The air to which the charged particles are added by the charged particle generator 2 is blown out from the outlet 124 as indicated by the arrow DR2. The air to which charged particles are added by the charged particle generation device 130 and the air to which charged particles are added by the charged particle generation device 2 are difficult to mix with each other. It is effectively suppressed that the charged particles are bonded and disappear and the amount of ions generated is reduced. According to the air conditioner 11, an air flow including high-concentration charged particles can be generated.

  As described above, the charged particle generation device 2 is configured to be detachable from the housing unit 102. When the user wants to irradiate the skin or hair with charged particles, the charged particle generating device 2 can be removed from the container 102 and used. According to the air conditioner 11, user convenience can be enhanced. On the other hand, by attaching the charged particle generating device 2 to the storage unit 102, the charged particle generating device 2 can be stored in the device main body 1 when the charged particle generating device 2 is not used. When the user wants to use the charged particle generation device 2, the user can easily find the place.

  The control circuit 260 of the charged particle generating device 2 receives the signal indicating the operation of the device main body 1 and controls the charged particle generating element 220 so as to be interlocked with the device main body 1. The user can control the charged particle generating device 2 and the device main body 1 without separately operating the charged particle generating device 2 and the device main body 1. According to the air conditioner 11, the convenience for the user can be further enhanced.

  More specifically, the device main body 1 includes an operation panel 104. The operation panel 104 is operated by a user. The control circuit 260 of the charged particle generation device 2 receives a signal indicating the operation content of the operation panel 104 and controls the charged particle generation element 220 so as to be interlocked with the device main body 1. Therefore, the user can control the charged particle generating device 2 by operating the device main body 1 in a state where the charged particle generating device 2 is attached to the housing portion 102. According to the air conditioner 11, the convenience for the user can be further enhanced.

  Furthermore, the charged particle generation device 2 includes a switch 208 that switches whether to supply a voltage from the power source (battery 207) to the charged particle generation element 220 by a manual operation. The connector 209 includes a power supply terminal 291 that is electrically connected to the battery 207 and the charged particle generation element 220 and receives power supplied from the device main body 1. When the charged particle generating device 2 is mounted on the device main body 1, the control circuit 260 controls the charged particle generating element 220 in response to a signal from the device main body 1.

  Electric power is supplied from the device body 1 to the charged particle generating element 220. The control circuit 260 starts and stops the charged particle generating element 220 in response to a signal from the device main body 1. Thereby, even if the charged particle generating device 2 is mounted on the device main body 1 with the switch 208 turned on, the charged particle generating element 220 can be started and stopped by operating the device main body 1. Furthermore, even when the charged particle generating device 2 is mounted on the device main body 1 with the switch 208 turned off, the charged particle generating element 220 can be started and stopped by operating the device main body 1.

  Thereby, for example, although the apparatus main body 1 is stopped, the charged particle generation device 2 can be prevented from continuing to operate. When the charged particle generation device 2 is operating even though the device main body 1 is stopped, the battery of the charged particle generation device 2 may be consumed. By stopping the charged particle generating device 2 when the device main body 1 is stopped, it is possible to prevent the battery of the charged particle generating device 2 from being consumed.

  Further, the power terminal 291 is electrically connected to the battery 207. When the charged particle generation device 2 is mounted on the device main body 1, the battery 207 is charged by receiving power from the device main body 1. Thereby, when a user removes the charged particle production | generation apparatus 2 from the apparatus main body 1 and uses the charged particle production | generation apparatus 2 next time, the use time of the charged particle production | generation apparatus 2 can be lengthened. According to the air conditioner 11, the convenience for the user can be further enhanced.

[Embodiment 2]
(Air conditioner 12)
With reference to FIG. 13, the air conditioner 12 in this Embodiment is demonstrated. In the air conditioner 11 of the above-described first embodiment, the charged particle generation device 130 is closer to the downstream side of the ventilation path 123 (closer to the air outlet 124 than the front end portion 125T of the guide portion 125 in the direction of the air flow generated by the blower 128. ) (See FIG. 6). According to this configuration, most of the charged particles generated by the charged particle generating device 130 can be taken out from the outlet 124.

  As shown in FIG. 13, in the air conditioner 12 of the present embodiment, the charged particle generation device 130 is located upstream of the airflow path 123 with respect to the leading end portion 125T of the guide portion 125 in the direction of the airflow generated by the blower 128 ( It is located near the blower 128). According to this configuration, the airflow including the charged particles generated by the charged particle generation device 130 flows into the housing unit 102. By supplying an air flow including charged particles to the inside of the housing portion 102, the inside of the housing portion 102 can be effectively sterilized.

[Embodiment 3]
(Air conditioner 13)
With reference to FIG. 14, the air conditioner 13 in this Embodiment is demonstrated. In the air conditioner 13, the accommodating part 102 is formed between the wind direction adjusting part 106 and the air path forming part 106T. When viewed from the ventilation path 123, both the charged particle generation device 130 and the charged particle generation device 2 are disposed on the first surface member 123A side.

  Even with this configuration, a part of the airflow passing through the ventilation path 123 is taken into the charged particle generator 2 through the suction port 230 (see FIG. 9). Under the present circumstances, the airflow more than the function of the ventilation fan 203 (refer FIG. 9) with which the charged particle generator 2 is provided is supplied in the charged particle generator 2 in response to the ventilation from the blower 128. The amount of airflow taken into the charged particle generation device 2 is such that the charged particle generation device 2 is attached to the storage unit 102 as compared to the case where the charged particle generation device 2 is removed from the storage unit 102 and used alone. More cases.

  The amount of charged particles generated from the charged particle generating device 2 is proportional to the amount of airflow supplied to the charged particle generating device 2. The amount of charged particles generated from the charged particle generation device 2 is larger than that when the charged particle generation device 2 is removed from the storage unit 102 and used alone, compared to the case where the charged particle generation device 2 is attached to the storage unit 102. If there are more. Therefore, even with the air conditioner 13, the charged particle generation device 130 and the charged particle generation device 2 can generate charged particles with high generation efficiency.

[Embodiment 4]
(Charged particle generator 2A)
The air conditioner in this Embodiment is demonstrated with reference to FIGS. In the air conditioner of the present embodiment, a charged particle generator 2A is used instead of the charged particle generator 2 in each of the above embodiments. FIG. 15 is a rear view showing the charged particle generator 2A. FIG. 16 is a side view showing the charged particle generator 2A.

  Referring to FIGS. 15 and 16, charged particle generation device 2 </ b> A further includes a conductor 270. The conductor 270 is formed in a plate shape, for example, and is provided on the outer surface of the case 201. The conductor 270 may be a metal thin film formed on the surface of the case 201 by means such as plating or vapor deposition. The conductor 270 may be housed inside the case 201.

  FIG. 17 is a diagram illustrating the accommodation unit 102 included in the air conditioner according to the present embodiment. Referring to FIG. 17, housing portion 102 is formed by wall 100 a and guide portion 125 that are part of housing 100. A conductive member 127 is disposed on the surface of the wall 100a (side surface 101 of the accommodating portion 102). The conductive member 127 is in electrical contact with the conductor 270 of the charged particle generator 2A. Although not shown in FIG. 17, for example, conductive member 127 is coupled to ground potential.

  When the charged particle generation device 2A is detached from the storage unit 102 and used alone, there is a possibility that electric charges are gradually accumulated in the charged particle generation device 2A. When the charged particle generation device 2A is attached to the storage unit 102 with charges accumulated in the charged particle generation device 2A, the amount of ions released from the charged particle generation device 2A may be reduced.

  According to the configuration shown in FIG. 17, the charge charged in the charged particle generation device 2 </ b> A can be released through the conductive member 127. As a result, it is possible to effectively suppress a reduction in the amount of ions released from the charged particle generation device 2A. Therefore, it is possible to suppress a decrease in the amount of ions released from the air conditioner.

(First modification)
As in the charged particle generation device 2 </ b> B illustrated in FIG. 18, the conductor 270 may be disposed only on the side surface of the case 201. Also with this configuration, the same operations and effects as described above can be obtained.

(Second modification)
As in the charged particle generation device 2 </ b> C illustrated in FIG. 19, the conductor 270 may be disposed only on the bottom surface of the case 201. Also with this configuration, the same operations and effects as described above can be obtained.

(Third Modification)
As in the charged particle generation device 2D illustrated in FIG. 20, the conductor 270 may be disposed only on the back surface of the case 201. Also with this configuration, the same operations and effects as described above can be obtained.

[Embodiment 5]
(Charged particle generator 2E)
The air conditioner in the present embodiment will be described with reference to FIGS. The air conditioner of the present embodiment includes a charged particle generation device 2E. The air conditioner of the present embodiment differs from the air conditioner of each of the above-described embodiments in the shape of the connector 131 of the device main body 1 and the shape of the connector 209 of the charged particle generation device 2E.

  FIG. 21 is a diagram illustrating a state in which the charged particle generating device 2E is accommodated in the device main body 1. Referring to FIG. 21, the connector 131 includes a plurality of connection terminals 131 a provided in a convex shape from the bottom surface 103 of the housing portion 102. The bottom 201e of the case 201 is provided with a plurality of connection terminals 209a formed so as to be recessed with respect to the surface of the case 201.

  FIG. 22 is a bottom view showing the connector 209 viewed from the bottom 201e of the case 201. FIG. Referring to FIG. 22, when a virtual equilateral triangle is drawn, three of a plurality (six in this embodiment) of connection terminals 209a are arranged one at a vertex of the equilateral triangle. Further, the remaining three of the six connection terminals 209a are arranged one by one on the three sides of the equilateral triangle. When the bottom 201e of the case 201 is viewed in plan, each connection terminal 209a has a circular outer shape.

  Two of the six connection terminals 209a correspond to the power supply terminal 291 and the signal input terminal 292 (see FIG. 11), respectively. The arrangement of the power supply terminal 291 and the signal input terminal 292 is not limited. The triangle defined by the six connection terminals 209a is not limited to a regular triangle. For example, the above triangle may be an isosceles triangle or an unequal triangle.

  FIG. 23 is a diagram schematically showing a cross section of the case 201 of the charged particle generation device 2E. Referring to FIG. 23, connection terminal 209 a is formed in a concave shape at bottom 201 e of case 201. The connection terminal 209 a is electrically connected to the substrate 260 a that is a component of the control circuit 260. On the other hand, the connection terminal 131 a of the connector 131 is formed on the substrate 132 a of the control circuit 132 and protrudes from the bottom surface 103 of the housing portion 102. The connection terminal 131a and the connection terminal 209a are fitted.

  A recess is formed at the bottom of the charged particle generating device 2E. The concave portion of the charged particle generating device 2E and the convex portion formed in the housing portion 102 are fitted. Thereby, the charged particle generation device 2E can be easily connected to the device main body 1. In a state where the charged particle generating device 2E is mounted on the device main body 1, the housing portion 102 of the device main body 1 can stably support the charged particle generating device 2E.

(Modification)
FIG. 24 is a plan view of the connector 209 viewed from the bottom 201e of the case 201 of the charged particle generation device 2F in the modification of the fifth embodiment. Referring to FIG. 24, a plurality of recesses 209b are formed in bottom 201e of case 201. The connector 209c is disposed in one of the plurality of recesses 209b. The connector 209c has a power supply terminal 291 and a signal input terminal 292. One of the six connection terminals 209a shown in FIG. 24 may be replaced with a connector 209c.

  25 is a cross-sectional view of the case 201 shown in FIG. Referring to FIG. 25, connector 131 b is formed on bottom surface 103 of housing portion 102. On the other hand, the connector 209c is disposed in one of the plurality of recesses 209b. The connectors 131b and 209c are connectors conforming to a standard for transmitting both power and control signals between two electrical devices. The connectors 131b and 209c are connectors conforming to, for example, a mini USB (Universal Serial Bus) standard. Also with this configuration, the same operations and effects as described above can be obtained.

  As mentioned above, although each embodiment based on this invention was described, each embodiment disclosed this time is an illustration and restrictive at no points. The technical scope of the present invention is defined by the terms of the claims, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  1 device body, 2, 2A, 2B, 2C, 2D, 2E, 2F charged particle generator (second charged particle generator), 11, 12, 13 air conditioner, 100 housing, 100a wall, 101, 201c side, 102 accommodating portion, 103 bottom surface, 104 operation panel, 106 air direction adjusting portion, 106P support portion, 106T air passage forming portion, 108 water supply tank, 110 water receiving portion, 112 air inlet, 114 power cord connection port, 115 power cord, 119 Water, 121, 122, 123 Ventilation path, 123A first surface member, 123B second surface member, 124, 240 outlet, 125 guide portion, 125T tip portion, 126 filter, 127 conductive member, 128 blower (first blower means ), 130 Charged particle generator (first charged particle generator), 131, 131b, 209, 209c Connector, 131a, 209a connection terminal, 132, 260 control circuit (control unit), 132a, 211, 260a board, 140 power supply unit, 151, 152, 153, 154 operation buttons, 155, 156, 157, 158, 159, 160 , 161, 162, 163 Indicator lamp, 201 case, 201a upper case, 201b lower case, 201d one end, 201e bottom, 203 blower fan (second ventilation means), 203a, 203b opening, 204a positive ion discharge part, 204b Negative ion discharge unit, 205a positive side rectifier, 205b negative side rectifier, 206 high voltage generator, 207 battery, 208 switch, 209b recess, 210 drive unit, 211a surface, 215 charged particle generator, 220 charged particle generator , 230 Suction port, 25 0 clip, 270 conductor, 280 charging circuit, 291 power supply terminal, 292 signal input terminal, AR1, DR1, DR2 arrows.

Claims (8)

A housing including an accommodating portion, a ventilation path, and an outlet provided at a downstream position of the ventilation path;
A first charged particle generating device disposed in the housing;
A first ventilation means arranged in the housing and for sending out the charged particles generated by the first charged particle generator from the outlet to the outside of the housing;
A second charged particle generating device that is detachably attached to the housing part and includes a second ventilation means,
The second charged particle generation device includes:
Power supply,
A high voltage circuit for generating a high voltage from a voltage supplied from the power source;
A charged particle generator that receives the high voltage from the high voltage circuit to generate charged particles, and
In a state where the second charged particle generating device is attached to the housing portion, the second charged particle generating device takes in a part of the airflow from the first ventilating means using the second ventilating means, and charges by generating particles out feed to the outside of the housing with the portion of the air flow,
The accommodating portion is provided with a conductive member that comes into electrical contact with the second charged particle generating device attached to the accommodating portion,
The electric charge charged in the second charged particle generating device is released through the conductive member.
air conditioner. A housing including an accommodating portion, a ventilation path, and an outlet provided at a downstream position of the ventilation path;
A first charged particle generating device disposed in the housing;
A first ventilation means arranged in the housing and for sending out the charged particles generated by the first charged particle generator from the outlet to the outside of the housing;
A second charged particle generating device that is detachably attached to the housing part and includes a second ventilation means,
The second charged particle generation device includes:
Power supply,
A high voltage circuit for generating a high voltage from a voltage supplied from the power source;
A charged particle generator that receives the high voltage from the high voltage circuit to generate charged particles, and
In a state where the second charged particle generating device is attached to the housing portion, the second charged particle generating device takes in a part of the airflow from the first ventilating means using the second ventilating means, and charges Generating particles to be sent to the outside of the housing together with the part of the airflow;
A control unit for sending a control signal for controlling the second charged particle generating device;
A plurality of connection terminals provided in a convex shape inside the housing portion, and
The second charged particle generation device attached to the housing receives the control signal through the connection terminal;
air conditioner. A power supply for supplying power to the second charged particle generating device;
The second charged particle generation device attached to the housing unit is charged by receiving the power through the connection terminal,
The air conditioner according to claim 2 . When a virtual equilateral triangle is drawn, three of the plurality of connection terminals are arranged one by one at three vertices of the equilateral triangle, and the other three of the plurality of connection terminals are One on each of the three sides of the equilateral triangle,
The air conditioner according to claim 2 or 3 . The ventilation path is provided with a guide portion that guides the part of the airflow from the first ventilation means to the second ventilation means of the second charged particle generation device attached to the housing portion.
The air conditioner according to any one of claims 1 to 4 . The housing includes a first surface member and a second surface member facing the first surface member for forming the ventilation path,
The first charged particle generating device is disposed on the first surface member side when viewed from the ventilation path,
The air conditioner according to claim 5 , wherein the second charged particle generation device is disposed on the second surface member side as viewed from the ventilation path. The first charged particle generation device is located on the upstream side of the ventilation path from the guide part,
The air conditioner according to claim 5 or 6 . The first charged particle generating device is located on the downstream side of the ventilation path with respect to the guide portion.
The air conditioner according to claim 5 or 6 .

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