JP3120097B2 - Negative ion generator - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a negative ion generator for purifying indoor air.

[0002]

2. Description of the Related Art A technique for cleaning indoor air by washing dirty air in a room with water and releasing negative ions generated by the Leonard effect due to the splitting of water droplets into the room to purify the room air has been known. (Japanese Patent Publication No. 5-58755). This device basically consists of a water splitting section and a gas-liquid separation section. In the water splitting section, a device that jets high-pressure water from a nozzle toward an impingement wall to split it into fine water droplets,
A device that sprays water onto a rotating disk and applies centrifugal force to the sprayed water to break up fine water droplets, using an ultrasonic humidifier,
A device that vibrates water to break it into fine water, or a device that sprays water on a rotating impeller and hits the water with the impeller to break it into fine water droplets is used. The gas-liquid separation section
For example, a cyclone separator. According to the cyclone separator, the humid air containing negative ions can be extracted to the outside by centrifugally separating the fine water droplets from the air while swirling the fine water droplet mixed air.

One of the attempts to reduce the size of the negative ion generator and use it as a home air cleaner is disclosed in Japanese Utility Model Application Laid-Open No. 4-1 / 4-1.
There is an air purifier described in Japanese Patent No. 26717. According to this air purifier, as shown in FIG.
Air is taken in through a dust collecting filter device 42 composed of a plurality of filters, and fine water droplets are jetted from an injection nozzle 44 in a gas-liquid contact portion 43 having a cyclone structure to make gas-liquid contact. After being sent to a droplet separation section 46 also having a cyclone structure and communicating with the liquid crystal section through which excess water is removed, clean air is discharged from an air discharge port 47.
In the figure, a pump 48 for pumping water to the injection nozzle 44, 4
9 is a water supply tank (removable cartridge tank), 5
Numeral 0 denotes a water tank for storing water to be jetted.

[0004]

As shown in FIG. 13, the water in the water tank 50 is supplied from a water supply tank 49. The water once stored in the water tank 50 is
Most of the water pumped up by the pump 48 and supplied to the nozzle 44 and ejected from the nozzle 44 is collected in the water tank 50 and used repeatedly. On the other hand, the water spouted from the nozzle 44 comes into contact with the air sucked from outside the machine by the operation of the fan 41, takes in the dirt, dust, cigarette smoke and the like contained in the air and is collected in the water tank 50. Therefore, the water in the water tank 50 is contaminated during repeated use, and it is inevitable that the water quality is reduced.

When the water in the water tank 50 becomes dirty, it may be replaced with new water.
Removing the water from the inside and refilling it with new water is troublesome, and if you continue to operate the device without noticing the need to change the water, not only will the negative ion generation function decrease, It can be a bad odor source, which is extremely inconvenient.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a negative ion generator having a function of notifying when to change water in a water tank.

In order to achieve the above object, the negative ion generator according to the present invention has operation control means. The apparatus is operated to pump up water supplied into the water tank, split the water into fine water droplets, and then generate air. A negative ion generator that performs liquid separation and blows humid air containing negative ions out of the machine,
Operation control means may feed water into the water tank, counting from when starting the operation of the apparatus stops the operation of the apparatus after a predetermined time has elapsed, or all SANYO prompting the stop of the operation, the operation
Started when the water tank was set in the device
Or when power is turned on to start operation of the equipment.
That is, when it is involved in water supply into the aquarium.

In addition, the apparatus has operation control means, and operates the apparatus to pump up water supplied into the water tank, split the water into fine water droplets, then perform gas-liquid separation, and remove humid air containing negative ions from the outside of the machine. The operation control means stops the operation of the device after a lapse of a predetermined time from the time when the amount of water in the water tank is equal to or more than a predetermined amount, or prompts the operation to stop. Things.

[0009]

[0010]

[0011] Further, after the operation of the apparatus is started, the time until the operation of the apparatus is stopped or the stop of the operation is prompted is the time during which the apparatus is operating, the time during which the apparatus is stopped operating, or the time when the apparatus is stopped. This is either the sum of the operating time and the time during which the operation of the device is stopped.

The operation control means has water quality detection means. The water quality detection means detects the water quality of the water in the water tank, and when the water quality lowers a predetermined level or less, the operation of the apparatus is controlled. It is to stop or to indicate the exchange of water in the aquarium.

[0013] The water quality detecting means, when detecting a decrease in the water quality and stopping the operation of the apparatus, performs a treatment of draining the water in the water tank together with the stop of the operation of the apparatus.

Further, the apparatus has operation control means, and operates the apparatus to pump up the water supplied into the water tank, split the water into fine water droplets, then perform gas-liquid separation, and remove humid air containing negative ions from the outside of the machine. The operation control means counts the elapsed time when the water level in the water tank is equal to or higher than a certain level or when at least one of the conditions when the operation of the apparatus is started is satisfied. Is started, the operation of the apparatus is stopped after a lapse of a predetermined time, and the water in the water tank is further drained.

[0015]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described below with reference to the drawings. 1 and 2 are diagrams showing an embodiment of a negative ion generator to which the present invention is applied. 1 and 2, the negative ion generator has a water splitting unit 1, a gas-liquid separating unit 2, a water tank 3, and a pump 4 in a body case 5.

The water splitting section 1 is a section that splits water supplied from the inside of the water tank 3 into fine water droplets and generates negative ions in nearby air. The gas-liquid separation unit 2 is a unit that receives air containing fine water droplets generated in the water splitting unit 1, centrifugally separates the fine water droplets from the air, and sends out humid air containing negative ions to the outside. Water is filled in the water tank 3, and the pump 4 pumps out the water in the water tank 3 and supplies it to the water splitting unit 1.

The water splitting section 1 and the gas-liquid separating section 2 are formed in the cyclone unit 6 and
Is composed of a combination of a first cyclone tube 7 and a second cyclone tube 8, and has a body integrally provided with a flange 9 projecting from the periphery. The first cyclone cylinder 7 and the second cyclone cylinder 8 have a vertically long cylindrical shape with an open lower edge, are arranged in parallel, and communicate with each other by a communication groove 6a. The cyclone unit 6 is composed of each cyclone cylinder 7,
The lower edge 8 is inserted into the water tank 3, and the flange 9 is set on the water tank 3 with the flange 9 seated on the opening edge 3 a of the water tank 3.

The water supply pump 4 is supported by the flange 9 of the cyclone unit 6 with its water inlet 4a facing downward.
It is immersed in the water filled in the tank at a certain interval from the bottom of the water tank 3.

An intake port 10 provided at a lower portion of the case 5 is connected to an upper portion of the first cyclone cylinder 7 via a duct 11, and an exhaust port 12 provided at an upper portion of the case 5 is connected to an exhaust passage 1.
The duct 11 is connected to the upper part of the second cyclone cylinder 8 through 3, and the duct 11 is provided with a blower 14 for sucking outside air. Inside the first and second cyclone cylinders 7 and 8, a blower 14 is provided.
Thus, a flow path of the outside air taken in is formed, and the outside air flows while rotating in the cylinders 7 and 8 sequentially, and is discharged from the exhaust port 12 into the outside air.

First cyclone cylinder 6 forming water splitting section 1
In the inside, there is provided a rotating body 15 which receives the supply of water in the water tank 3 and jets it into the first cyclone cylinder 7.

In this embodiment, an inner cylinder 16 is provided concentrically within the first cyclone cylinder 7, and the inner cylinder 16 is provided with a rotating body 15 and a ring 17 serving as a collision wall.
A motor 18 for rotating the rotating body 15 is mounted in the inner cylinder 16, and its rotating shaft is mounted on a shaft hole of the rotating body 15, and the rotating body 15 is installed in a horizontal position in the body of the first cyclone cylinder 7. doing.

The rotating body 15 is a hollow body having a water receiving portion 19 on an upper surface and a water discharging portion 20 on a peripheral surface.

The water is supplied to the rotating body 15 through the supply pipe 21.
Supplied from above. The water supply pipe 21 is connected to the water outlet 4 b of the pump 4, rises upward, is inserted into the inner cylinder 16 from above the first cyclone cylinder 7, and is opened on the rotating body 15. . The water received in the rotating body 15 is converted into the rotating direction of the rotating body 15 and is sprayed in the centrifugal direction from the peripheral water discharge section 24.
7 and breaks into fine water droplets. The surface on which the water spouted from the rotating body 15 collides is a collision wall that splits the water into fine water droplets. The released water is split into fine water droplets to generate negative ions in the air, and is sent into the gas-liquid separation unit 2 by the wind force of the blower 14.

The first cyclone cylinder 7 forming the gas-liquid separation section 2 receives air containing fine water droplets generated in the water splitting section 1 and centrifugally separates the fine water droplets from the air to contain negative ions. The humid air is sent from the exhaust port 12 to the outside air.
The inside of the second cyclone cylinder 8 is hollow, forms a swirling flow path of air, and has an upper end communicating with an exhaust port 12 through an exhaust passage 13.

The cartridge tank 22 is a water supply tank for supplying or replenishing water into the water tank 3. The cartridge tank 22 is housed in a space in the case 5 formed above the pump 4, and is detachably held by the flange 9. The water filled therein is transferred into the water tank 3 in an inverted posture.

The water in the water tank 3 is pumped up by the water supply pump 4 and supplied to the water splitting unit 1. Excess water generated in the water splitting unit 1 and water centrifugally separated in the gas-liquid separation unit 2 are removed from each cyclone cylinder. It is returned into the water tank 3 along the inner walls 7 and 8. Aquarium 3
Has a drain port 23 at the bottom thereof, and a drain pump 24 is connected to the drain port 23.

When the water in the water tank is contaminated or when the operation of the apparatus is stopped for a long time, the drain pump 24 is activated to discharge the water in the water tank 3. When the water in the water tank 3 is discharged, the water in the water supply pump 4 and in the pipe 21 leading from the water supply pump 4 to the water splitting unit 1 also falls into the water tank 3 from the water suction port 4a, and the pump 4 and the pipe The water in 21 is completely drained.

The present invention has operation control means. Specifically, a timer is used as the operation control means. The timer stops the operation of the apparatus after a predetermined time (for example, 48 hours) has elapsed since the first operation was started after the water was newly supplied into the water tank. FIG. 3 shows a connection diagram of the timer T. In the present invention, the operation of the device specifically means the blower 1
4, the operation of the motor 18, the pump 4, and the like. Blower 1
4 stops the suction of the outside air into the machine body and the blowing to the outside of the machine, stops the motor 18 to stop the injection of the water supplied to the rotating body 15, and further stops the pump 4 to stop the rotation. Water supply to the body 15 is stopped.
Once the timer T shuts off the power supply circuits of the blower 14, the motor 18, and the pump 4, the operation cannot be performed even if these power switches are turned on.

"When the operation is started" means when the power of the apparatus is turned on and the blower, the motor, and the pump are started. In the present invention, for example, the cartridge tank 22 which is filled with fresh water is used for the body. When set in the case 5, when water in the cartridge tank 22 is supplied into the water tank, or when the power switch is turned on to start the apparatus after the cartridge tank 22 is set in the body, The time when it is involved in supplying water into the water tank can be used to mean "when the first operation is started."

However, since the cartridge tank 22 may be set after the power of the apparatus is turned on, the timing for starting the "first operation" may be determined by satisfying the AND condition between the setting of the cartridge tank 22 and the power on. Good. FIG. 4 shows a flowchart in the case where the operation of the device is stopped after a predetermined time from the start of the first operation.

In FIG. 4, first, it is determined whether or not the operation is the first operation (step 101). If the operation is the first operation, counting of the elapsed time is started (step 102). From this count, it is determined whether a predetermined time (48 hours) has elapsed (step 10).
3) When the predetermined time has elapsed, the operation of the apparatus is stopped (step 104), and a display prompting the drainage of the water in the water tank (LED lighting) is displayed (step 105).
Step 104 is not necessarily limited to the case where the operation of the apparatus is stopped, and may be such that a display or an alarm is issued to prompt the user to stop the operation of the apparatus. The display prompting the user to stop the operation of the apparatus also means prompting the drainage of water in the water tank. Therefore, after a predetermined time has elapsed, the display of step 105 can be performed as a display prompting the user to stop the operation. This is the same in the following embodiments.

On the other hand, if it is not the first operation (step 106), it is immediately determined whether a predetermined time has elapsed since the first operation (step 103). If the predetermined time has not elapsed, the elapsed time is counted continuously. Is continued.

In the present invention, the operation of the apparatus can be controlled according to the condition as to whether water is contained in the water tank 3 or not. FIG. 5 shows an example in which the water level in the water tank 3 is detected and added to the operation control conditions. In FIG. 5, the water level in the water tank 3 is equal to or higher than a certain value (for example, 2/3 or higher) during operation of the apparatus.
It is determined whether or not the water level is 2/3 (step 201).
At the above time, counting of the elapsed time is started (step 202), and it is determined whether a predetermined time (48 hours) has elapsed (step 203). After the elapse of 48 hours, the operation is stopped or the operation is stopped (step 20).
4) A display prompting the drainage of water in the water tank is displayed (step 205).

When the water level is equal to or less than 2/3, the elapsed time from the start of operation is determined. When 48 hours have already passed, the operation stop condition is satisfied. Operation is possible until the elapsed time has arrived.

In the present invention, the operation control means includes a water tank 3
The operation elapsed time can be counted by selectively judging the condition of whether water is contained in the inside and the condition of whether the operation is the first operation. In FIG. 6, it is determined whether the water level in the water tank 3 is equal to or higher than a predetermined value (for example, 2/3 or more) (step 301), or it is determined whether the operation is the first operation (step 302). When the water level is equal to or higher than a certain value or when the first operation is satisfied, counting of the operation elapsed time is started (step 303), and after a predetermined time elapses (step 304) as in FIG. Is stopped or the operation is stopped (step 305), and a display (LED lighting) indicating the drainage of the water in the water tank 3 is displayed (step 30).
6). If it is not the first operation, the elapsed time is judged (step 304). If the elapsed time has come, the operation is stopped (step 305), and an indication to drain the water is made (step 306). 5 and 6
In the embodiment shown in (2), the water level in the water tank 3 is not less than a certain level, and the water level in the water tank 3 is not less than ／ of the water level as an example. Is meant. However, there is no problem if the water level at which operation can be actually performed is lower, for example, 1/3 or more. FIG.
Shows an example in which the operation of the apparatus is controlled based on an AND condition when the water level is equal to or more than 1/3 and the water supply tank once removed from the body is set in the body again.

That is, in this embodiment, when the water level is detected to be 1/3 or more (step 401) and when the water supply tank is set (step 40).
Starting from 2), counting of the time until drainage is started (step 403), and when the elapsed time reaches the set time (step 404), the drainage is prompted (step 40).
5) Things. In this embodiment, the drainage pump 24 may be further activated to automatically drain the water in the water tank 3.

FIG. 8 shows an example of the operation panel 25. The operation panel 25 includes a power-on switch (operation) S ₁ , an air flow intensity switch S ₂ for manual operation, a high / low switch S ₃ for setting humidity, an automatic operation switch S ₄ , and the like. a switch S ₅ for focusing operation. Priority running switch S _5, is switched to automatic operation, temperature, wind control is obtained by adding the power consumption control conditions. Mode plus the temperature condition in the automatic operation "refreshing" mode for controlling the wind "Good night", the mode for controlling the power consumption is indicated in clearly windows W ₁ with a display of "energy saving". In addition, on the operation panel 25,
In addition to the push button S ₆ of the drainage operation, the display of the amount of water in the water tank, water supply, water exchange prompting the prompting or draining operation is stopped and a display P such as loading of the water supply tank.

Further, in the present invention, the time period from when the operation is started or when a predetermined level or more of water is detected to the time when the operation of the apparatus is stopped or the operation is stopped is set to, for example, 48 hours. Although the time is a unit of several days, this time may be a time obtained by integrating only the time when the apparatus is actually operating, or the time when the apparatus is stopped or the time when the apparatus is stopped. It may be a time obtained by adding the time during operation and the time during which operation is stopped.

In the above embodiment, various examples of the device for detecting the water level in the water tank 3 are conceivable, but FIG. 9 shows an example using ultrasonic waves. That is, under the control of the microcomputer 26, the ultrasonic wave output to the transmitting unit 27 is transmitted from the transmitter 28 toward the water surface in the water tank 3, and the reflected wave reflected on the water surface is received by the receiver 30 of the receiving unit 29, The water level is detected by calculating the time from transmission to reception of the ultrasonic wave and the distance from the transmitter 28 or the receiver 30 to the water surface. With this device, since there is no contact, the water level can be accurately measured irrespective of water contamination.

As described above, in the embodiment, an example has been described in which the operation is started from the first operation or by detecting the water level in the water tank, and the operation of the apparatus is stopped after a predetermined time has elapsed. The degree of progress of the contamination is not uniform and varies depending on the installation environment of the apparatus.

For example, when the apparatus is used in a room with a lot of smokers or a room with a lot of dust, a situation arises in which the operation must be stopped before the scheduled regular operation time arrives. In order to prepare for such a situation, it is also important to detect the degree of contamination of the water in the water tank and to forcibly stop the operation of the apparatus when the water becomes dirty beyond a predetermined standard. FIG.
0 is an example of optically detecting the transparency of water.

That is, in FIG. 10, the operation control means includes water quality detection means, and the water quality detection means detects the water quality in the water tank and stops the operation of the apparatus when the water quality falls below a predetermined standard. is there. In this embodiment,
A transparent part 31 is provided in a part of the water tank 3 or in a part of a pipe 21 leading from the water tank 3 to the water splitting unit 1, and a light emitting element 32 and a light receiving element 33 are arranged facing each other with the transparent part 31 interposed therebetween. The light emitted from the light emitting element 32 is received by the light receiving element 33 under the control of the microcomputer 26. As a result, when the transparency of the water flowing in the pipeline 21 drops below a predetermined reference value, it is determined that the water in the water tank 3 needs to be replaced, and the microcomputer 26 issues a command to stop the operation of the apparatus or the water tank 3. Output the forced drainage command. However,
By purifying the water in the aquarium, it is possible to suppress a decrease in water quality.

FIG. 11 shows an example of removing water stain components in the water tank 3. In FIG. 11, a hollow fiber membrane 34 and a flow sensor 35 are provided in a pipe 21 connecting the water tank 3 and the water splitting section 1.
The water in the water tank 3 is supplied to the water splitting unit 1 through the hollow fiber membrane 34, and the amount of flowing water is detected by the flow rate sensor 35. While the hollow fiber membrane 34 functions, the dirt component in water,
Bacteria are removed. However, clogging is inevitable. As the clogging of the hollow fiber membrane 34 progresses, the flow rate decreases. In the present embodiment, the operation limit flow rate or the life of the hollow fiber membrane is set in advance, and when the flow rate indicated by the flow rate sensor 35 reaches the operation limit flow rate, or when the hollow fiber membrane 3
The life of the hollow fiber membrane 34 is notified when the life of the sample No. 4 reaches the end of its life. However, in the normal case, the flow rate is expected to decrease linearly as shown in FIG. operating limits flow before the lifetime P of the hollow fiber membrane 34 is exhausted by back calculation from (e.g. 1 month ago) flow rate determines the, is possible to broadcast the life warning P ₁ of the hollow fiber membrane when it reaches the flow rate it can.

According to this embodiment, even if germs are generated in the water tank 3, the germs can be removed and sent to the water splitting unit 1, and when the hollow fiber membrane 34 is deteriorated, its replacement is promoted. Always use clean water to generate clean negative ions in the air.

[0045]

As described above, according to the present invention, the operation of the apparatus is started by the operation of the timer after a predetermined time has elapsed after the water was newly supplied to the water tank or after a predetermined amount of water was supplied into the water tank. Is stopped or nodded and stopped, so there is no inconvenience that the operation can be continued for a long time with dirty water. Can be performed at an appropriate time. Of course, if the quality of the water in the water tank is significantly reduced before the preset time has elapsed, the operation of the apparatus can be stopped and automatic drainage can be performed to prevent the use of contaminated water.

[Brief description of the drawings]

FIG. 1 is a diagram showing one embodiment of a negative ion generator to which the present invention is applied.

FIG. 2 is a perspective view of a negative ion generator.

FIG. 3 is a connection diagram of a timer.

FIG. 4 is a diagram showing a flowchart of the first embodiment of the present invention.

FIG. 5 is a diagram showing a flowchart of a second embodiment of the present invention.

FIG. 6 is a diagram showing a flowchart of a third embodiment of the present invention.

FIG. 7 is a diagram showing a fourth embodiment of the present invention.

FIG. 8 is a diagram illustrating an example of an operation panel.

FIG. 9 is a diagram showing an example of a device for detecting a water level in a water tank.

FIG. 10 is a diagram illustrating an example of a water quality detection unit.

FIG. 11 is a diagram showing an apparatus for removing water stains in a water tank.

FIG. 12 is a diagram showing the deterioration characteristics of a hollow fiber membrane.

FIG. 13 is a diagram showing an example of a conventional negative ion generator used for an air purifier.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Water splitting part 2 Gas-liquid separation part 3 Water tank 3a Opening edge 4 Pump 4a Water inlet 5 Case 6 Cyclone unit 6a Communication groove 7 1st cyclone cylinder 8 2nd cyclone cylinder 9 Flange 10 Intake port 11 Duct 12 Exhaust port 13 Exhaust passage 14 Blower 15 Rotating body 16 Inner cylinder 17 Ring 18 Motor 19 Receiving part 20 Water discharging part 21 Water supply pipe 22 Cartridge tank 23 Drain outlet 24 Drain pump 25 Operation panel 26 Microcomputer 27 Transmitting unit 28 Transmitter 29 Receiving unit 30 Receiver 31 transparent part 32 light emitting element 33 light receiving element 34 hollow fiber membrane 35 flow rate sensor T timer

────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-6-2699491 (JP, A) JP-A-7-88170 (JP, A) JP-A-7-758 (JP, A) (58) Survey Field (Int.Cl. ⁷ , DB name) A61L 9/00-9/22 B01D 53/34-53/96

Claims (6)

(57) [Claims] 1. An apparatus having operation control means, wherein the apparatus is operated to pump up water supplied into a water tank and split the water into fine water droplets.
Subsequently, a negative ion generator for performing gas-liquid separation and blowing humid air containing negative ions to the outside of the device, wherein the operation control means supplies water into the water tank and starts counting from the time when the operation of the device is started. stopping the operation of the apparatus after a predetermined time has elapsed, or all SANYO prompting the stop of the operation, started operation and
When the water tank is set in the device or when the device
Start the operation of the tank as if the power was turned on.
Negative ion generator characterized in that it is involved in the water supply to the negative ion generator. 2. An apparatus having operation control means, wherein the apparatus is operated to pump up water supplied into a water tank and split the water into fine water droplets.
Next, a negative ion generator for performing gas-liquid separation and blowing humid air containing negative ions to the outside of the machine, wherein the operation control means calculates a predetermined amount from the time when the amount of water in the water tank is equal to or more than a predetermined amount. A negative ion generator, wherein the operation of the apparatus is stopped after a lapse of time, or the operation is prompted. 3. The time from the start of the operation of the apparatus to the stop of the operation of the apparatus or the prompting of the stop of the operation is the time during which the apparatus is operated, the time during which the apparatus is stopped, or the time when the apparatus is stopped. 3. The negative ion generator according to claim 1, wherein the negative ion generator is one of a total of a time during which the apparatus is operated and a time during which the apparatus is stopped. 4. 4. The operation control means includes water quality detection means. The water quality detection means detects the water quality of the water in the water tank and, when detecting a decrease in water quality below a predetermined standard, operates the apparatus. 3. The negative ion generator according to claim 1, wherein the negative ion generator is configured to stop the operation or to display replacement of water in the water tank. 5. The apparatus according to claim 1 , wherein the water quality detecting means performs a treatment for draining water in the water tank together with the operation stop of the apparatus when the operation of the apparatus is stopped by detecting a decrease in water quality. 5. The negative ion generator according to 4 . 6. An apparatus having operation control means, wherein the apparatus is operated to pump up water supplied into the water tank and split the water into fine water droplets.
Subsequently, a negative ion generator for performing gas-liquid separation and blowing humid air containing negative ions to the outside of the machine, wherein the operation control means, when the water level in the water tank is equal to or higher than a certain level,
Alternatively, counting of the elapsed time is started when at least one of the conditions is satisfied when the operation of the apparatus is started, the operation of the apparatus is stopped after a predetermined time has elapsed, and the water in the water tank is further drained. A negative ion generator characterized by the above-mentioned.