TWM499025U - Indoor plant source negative ions boosting device with electric shock prevention - Google Patents

Description

Anti-electric shock indoor plant source negative ion surge device

The invention relates to a negative ion generating device, in particular to an indoor electric source negative ion augmenting device for preventing electric shock.

The rapid development of global industrialization, urbanization and modernization has led to increasing air pollution. Especially in densely populated metropolises, various industries and vehicles have concentrated a large amount of exhaust gas, making air pollution in cities more serious. In the urban interiors with high-rise buildings and relatively small living spaces, the harmful gases released by modern electrical appliances and building materials have once again aggravated indoor air pollution. Therefore, the purification and improvement of indoor air has become one of the problems that need to be solved in the current urban development.

The World Health Organization has confirmed that the concentration of negative ions in the air is an important indicator for assessing air quality, that is, the concentration of negative ions is the key to the quality of air. Therefore, products for purifying air such as an air negative ion generator capable of producing negative ions and a plant negative ion generator have appeared on the market. The artificial air anion generated by the air negative ion generator and the plant source negative ion released by the plant itself are very different, because the negative ions released by the plant are close to the negative ions of the original forest plant source, which has greater benefits for human health.

However, existing plant anion generators do not have electric shock protection facilities and have safety concerns in use.

Therefore, the object of the present invention is to provide an anti-shock, indoor plant source negative ion surge device capable of stimulating a plant to release a large amount of negative ions.

Therefore, the novel anti-shock indoor plant source negative ion surge device comprises a casing, a flower pot, a negative high voltage pulse output module and a distance sensor. The outer casing includes an annular outer wall, an annular inner wall, and a bottom plate disposed between the annular outer wall and the annular inner wall; the flower pot is disposed in an inner cavity surrounding the annular inner wall of the outer casing, and the outer casing A bottom of the flower pot is provided with a first joint extending into the flower pot, and the bottom plate of the outer casing is provided with a second joint; the negative high voltage pulse output module is disposed in the outer casing and comprises: a high voltage The pulse generating circuit has a first electrode electrically coupled to the first contact, and a second electrode electrically coupled to the second contact; a driving circuit electrically coupled to the high voltage pulse generating circuit; And a controller electrically coupled to the driving circuit, and controlling the driving circuit to drive the high voltage pulse generating circuit according to an activation signal to generate a negative high voltage pulse and outputting to the first electrode; the distance sensor and the The controller is electrically coupled, and outputs a control signal to the controller when the distance between the detected object and the object is less than a predetermined value, so that the driving circuit stops operating according to the control signal.

Preferably, the negative high voltage pulse output module further includes a high speed optocoupler electrically coupled between the controller and the driving circuit, and the controller generates a control signal according to the startup signal, and the high speed is generated through the high speed Light The electrical coupler outputs the control signal to the driving circuit to drive the high voltage pulse generating circuit to generate the negative high voltage pulse.

Preferably, the high voltage pulse generating circuit comprises a step-up transformer, a self-recovering fuse and a diode, and one end of a primary side coil of the step-up transformer is electrically coupled to the DC power source via the self-recovering fuse, and The other end of the primary side coil is electrically coupled to the driving circuit, and one end of the primary side coil of the step-up transformer is electrically coupled to the first electrode, and the other end thereof is connected to the diode via the reverse connection. The second electrode is electrically coupled.

Preferably, the negative high voltage pulse output module further includes a first resistor electrically coupled between an output of the controller and an input of the high speed optocoupler, and an end of the output of the controller The second resistor is electrically coupled to the other end and grounded at the other end.

Preferably, the anti-shock indoor plant source negative ion surge device further includes a third resistor electrically coupled between the first electrode and the second electrode.

Preferably, the anti-shock indoor plant source negative ion surge device further comprises a temperature and humidity sensor, a humidifier and a leafless fan disposed on the outer casing and electrically coupled to the controller, the temperature and humidity sense The detector detects a temperature and humidity value in the environment and transmits the value to the controller, and the controller controls the difference according to the difference between the received temperature and humidity value and a preset temperature and humidity preset value thereof. The operation of the humidifier and the wind speed and direction of the bladeless fan.

Preferably, the anti-shock indoor plant source negative ion surge device further comprises an negative ion concentrated on the outer casing and electrically coupled to the controller. a detector that detects a negative ion concentration value in the environment and transmits the value to the controller, the controller according to the difference between the received negative ion concentration value and a predetermined negative ion concentration preset value therein, The driving circuit is controlled to be activated or not to maintain the negative ion concentration in a predetermined range.

Preferably, the electric shock-proof indoor plant source negative ion surge device further comprises a agave plant, and the inner basin is filled with a culture (soil or culture solution) to plant the agave plant, the first The junction contacts the culture in the inner pot such that the negative high pressure pulse is transmitted through the culture to the root of the agave plant, thereby stimulating the agave plant to release negative ions. And preferably, the agave plant is a Phnom Penh agave.

Preferably, the outer casing further comprises a carrier disk that is disposed above the annular outer wall and an outer chamber surrounded by the annular inner wall, and the center of the carrier disk has a pair of openings corresponding to the inner chamber.

Preferably, the disk surface of the carrier disk is formed with a plurality of perforations, and an annular card slot corresponding to the annular inner wall is protruded from the periphery of the opening of the carrier disk, and an opening circumference of the flower pot and the ring shape The top end of the card slot abuts, so that the flower pot is suspended on the carrier tray.

Alternatively, the anti-shock indoor plant source negative ion surge device further includes a plurality of flower pots, and the tray surface of the carrier tray further defines a plurality of openings corresponding to the outer chambers for the flower pots to be suspended therein.

The present invention is arranged in the outer casing, the flowerpot is spaced apart from the outer casing, and the first electrode is in contact with the flowerpot, and the second electrode is spaced apart from the first electrode and is in contact with the outer casing, which can effectively improve the plant production. Negative ion concentration, and by setting the distance sensor and the third resistor, Prevents electric shock (electric shock) when objects come into contact with plants, and can adjust the negative ion concentration in the environment at the right time by setting the temperature and humidity sensor, humidifier, bladeless fan and negative ion concentration detector, and controller control. To maintain the concentration of negative ions in the environment within the optimal range, and to achieve the purpose of purifying indoor air and improving indoor air quality.

1‧‧‧Shell

2‧‧‧ flowerpots

3‧‧‧ Negative high voltage pulse output module

4‧‧‧Remote control

11‧‧‧ annular outer wall

12‧‧‧Circular inner wall

13‧‧‧floor

14‧‧‧second junction

15‧‧‧Base

16‧‧‧External chamber

17, 17'‧‧‧ Carrying tray

21‧‧‧ bottom

22‧‧‧ first joint

23‧‧‧ openings

31‧‧‧ Controller

32‧‧‧High speed optocoupler

33‧‧‧Drive circuit

34‧‧‧High voltage pulse generating circuit

35‧‧‧Remote signal receiving circuit

36‧‧‧Distance sensor

37‧‧‧ Temperature and Humidity Sensor

38‧‧‧Humidifier

39‧‧‧Faceless fan

51‧‧‧ Negative ion concentration detector

121‧‧‧ inner chamber

171‧‧‧ openings

172‧‧‧Ring card slot

173‧‧‧

174‧‧‧Perforation

175‧‧‧ large opening

176‧‧‧Small opening

301‧‧‧First electrode

302‧‧‧second electrode

331‧‧‧ Half-bridge wafer

332‧‧‧MOS switch

340‧‧‧Rectifier circuit

341‧‧‧Self-recovery fuse

342‧‧‧DC power supply

T‧‧‧Step-up transformer

N1‧‧‧ primary side coil

N2‧‧‧second side coil

R1‧‧‧first resistance

R2‧‧‧second resistance

R3‧‧‧ third resistor

Other features and effects of the present invention will be apparent from the following description of the drawings, wherein: FIG. 1 is a preferred embodiment of the novel anti-shock, indoor plant source negative ion surge device for planting a agave FIG. 2 is a perspective exploded view of the indoor plant source negative ion surge device of the present embodiment for preventing electric shock; FIG. 3 is a perspective view of the indoor plant source negative ion surge device of the present embodiment; FIG. 3 is a cross-sectional view of the 2-2 hatching; FIG. 5 is a circuit diagram of the negative high-voltage pulse output module of the embodiment; FIG. 6 is a view showing that the first electrode and the second electrode of the high-voltage pulse generating circuit of the embodiment are not transparent to the inner basin and The housing is electrically connected; FIG. 7 shows that the first electrode and the second electrode of the high-voltage pulse generating circuit of the embodiment are electrically connected through a wire connecting the inner basin and the outer casing; FIG. 8 shows that the gold-plated agave used in the embodiment continuously releases negative ions. And the concentration of the released negative ions; and FIG. 9 is a perspective view of the outer casing of another preferred embodiment of the indoor plant source negative ion surge device of the present invention.

Referring to FIG. 1 to FIG. 4, a preferred embodiment of the indoor plant source negative ion surge device of the present invention mainly comprises a casing 1, a flower pot 2 and a negative high voltage pulse output module 3. The outer casing 1 includes an annular outer wall 11, an annular inner wall 12, and a bottom plate 13 disposed between the annular outer wall 11 and the annular inner wall 12. The flower pot 2 is disposed in an inner chamber 121 surrounded by the annular inner wall 11 of the outer casing 1. The flower pot 2 is filled with a culture such as soil or culture liquid, and a bottom portion 21 of the flower pot 2 is provided with a flower extending into the flower pot 2. The first joint 22 in the basin 2, and the bottom plate 13 of the outer casing 1 is provided with a second joint 14. In addition, a base 15 may be separately disposed below the outer casing 1 for receiving the negative high voltage pulse output module 3.

The negative high voltage pulse output module 3 has a first electrode 301 and a second electrode 302 that output a negative high voltage pulse, and the first electrode 301 is electrically coupled to the first contact 22, and the second electrode 302 and the second contact 14 is electrically coupled to form a virtual circuit through the air passing through the first electrode 301 and the second electrode 302.

Thereby, as shown in FIG. 1, when the flower pot 2 is filled with a culture (soil or culture liquid) and planted with a agave plant 100, such as a gold-plated agave, the first joint 22 contacts the flower pot 2 The medium culture transmits a negative high-pressure pulse to the root of the agave plant 100 via the culture and stimulates it, so that the agave plant 100 releases a large amount of negative ions, thereby exerting the function of purifying the indoor air, thereby achieving the novel the goal of. Moreover, the gold-faced agave in this embodiment is characterized in that it has a long time of releasing negative ions, is drought-tolerant, resistant to yin and is easy to maintain indoors.

More specifically, the annular outer wall 11 and the annular inner wall 12 enclose an outer chamber 16. The outer casing 1 of the present embodiment further includes a carrier disk that is annularly disposed between the annular outer wall 11 and the annular inner wall 12. 17. The carrier tray 17 is located above the outer chamber 16 and has an opening 171 in the center of the carrier tray 17.

Preferably, an annular V-shaped annular card slot 172 is protruded from the periphery of the opening 171 of the carrier disk 17 to be engaged with the upper edge of the annular inner wall 12, and the outer edge of the carrier disk 17 is also protruded from the ring. The annular wall of the outer wall 11 allows the carrier disk 17 to be firmly fixed above the outer chamber 16, and when the flowerpot 2 is placed in the inner chamber 121, the periphery of an opening 23 of the flower pot 2 abuts against the top end of the annular card slot 172. The annular inner wall 12 cooperates with the annular card slot 172 to provide sufficient structural strength to allow the flower pot 2 to be stably suspended in the inner chamber 121.

In addition, a plurality of perforations 174 are formed in the disk surface 173 of the carrier tray 17, and the perforations 174 can be used to secure the roots of other plants when the outer chamber 16 is also planted with other plants.

Furthermore, as shown in FIG. 5, the negative high voltage pulse output module 3 of the present embodiment mainly includes a controller 31, a high speed photocoupler 32 electrically coupled to the controller 31, and a high speed optocoupler 32. The coupled drive circuit 33 and a high voltage pulse generating circuit 34. The controller 31 can adopt the STC11 series single-chip microcomputer, according to a negative ion concentration value and a negative ion continuous release time set by a remote controller 4 (or a keyboard), performing a table lookup, timing and the like and outputting a 5V pulse signal of the corresponding parameter, The 5V pulse signal is optically isolated by signal noise of the high speed photocoupler 32, and then output to the drive circuit 33 for signal shaping via the half bridge wafer 331 in the drive circuit 33. After amplification, the output 5V high current pulse signal drives the MOS switch 322 to output a 12V high current high voltage pulse modulation signal to the high voltage pulse generation circuit 34, boosts it via a step-up transformer T of the high voltage pulse generation circuit 34, and boosts the voltage via the step-up rectifier. The circuit 340 rectifies and outputs a negative high voltage pulse to the first electrode 301 and the second electrode 302, so that the negative high voltage pulse electrically shocks (stimulates) the root of the agave plant 100 through the culture, so that the agave plant 100 releases negative ions. And because the outer casing 1 and the flower pot 2 are not electrically connected, the first electrode 301 and the second electrode 302 are not electrically connected, but a virtual circuit is formed through the air, so that the agave plant 100 can release a large amount of space. Negative ions.

The high speed photocoupler 32 can provide a good isolation between the controller 31 and the drive circuit 33. In the embodiment, the negative high voltage pulse output module 3 further includes a remote signal receiving circuit 35 for receiving an input signal from the remote controller 4.

As shown in FIG. 5, one end of the primary side coil N1 of the step-up transformer T of the high voltage pulse generating circuit 34 is electrically coupled to the DC power source 342 via a self-recovering fuse 341, and the other end of the primary side coil N1 and the driving circuit are provided. 33 is electrically coupled, whereby when the current flowing through the primary side coil N1 is excessive (overcurrent), the self-recovery fuse 341 is rendered non-conductive or insulated when the temperature rises, so as to protect the circuit from being burnt due to overcurrent. The self-recovery fuse 341 is restored to the on state until the temperature is lowered and no large current is generated. One end of the secondary side coil N2 of the step-up transformer T is electrically coupled to the first electrode 301, and the other end thereof is electrically coupled to the second electrode 302 via a reverse-connected diode D.

Moreover, in this embodiment, a first resistor R1 is electrically coupled between an output end of the controller 31 and an input end of the high speed photocoupler 32, and one end is electrically coupled to the output end of the controller 31, and the other end is grounded. a second resistor R2. By the voltage dividing circuit composed of the first resistor R1 and the second resistor R2, the controller 31 can be prevented from damaging the high-speed photocoupler 32 due to excessive voltage at the startup, and the controller 31 can be activated to output the high-speed photocoupler. The current of 32 is not too large to protect the high speed optocoupler 32.

In addition, when the root of the plant 100 is stimulated by a negative high-voltage pulse, the tip end of the blade of the plant 100 generates a tip discharge, so in order to prevent the human or animal from accidentally touching the plant 100 and electric shock, as shown in FIGS. 3 and 5, The negative high voltage pulse output module 3 of the embodiment further includes at least one distance sensor 36, such as an ultrasonic sensor, disposed on the annular outer wall 11 of the outer casing 1 and electrically coupled to the controller 31, for the tongue An ultrasonic electronic fence is formed around the orchid 100, and detects that an object is at a distance less than a predetermined value, for example, 20 cm, and outputs a control signal to the controller 31 to control the driving according to the control signal. Circuit 33 ceases to operate, causing high voltage pulse generating circuit 34 to stop outputting a negative high voltage pulse.

Moreover, at the moment when the high-voltage pulse generating circuit 34 stops outputting the negative high-voltage pulse, the blade end portion of the plant 100 still has electric charge, and therefore, in order to further prevent the object from coming into contact with the blade of the plant 100, the high-voltage pulse generating circuit of the present embodiment The 34 further includes a third resistor R3 electrically coupled between the first electrode 301 and the second electrode 302, whereby when the high voltage pulse generating circuit 34 stops outputting the negative high voltage pulse, the charge remaining on the blade of the plant is Via the first electrode 301, the third resistor R3, and the second electrode 302 A discharge circuit is formed to discharge to prevent electric shock. And preferably, the resistance of the third resistor R3 is 1100 M ohms (Ω).

Furthermore, as shown in FIG. 3 and FIG. 5, the present embodiment can also be provided with a temperature and humidity sensor 37 and a humidifier 38 (including a humidifier control) electrically coupled to the controller 31. Circuit) and a bladeless fan 39 (including a fan control circuit). The temperature and humidity sensor 37 detects a temperature and humidity value in the environment and transmits it to the controller 31, and the controller 31 determines the difference between the received temperature and humidity value and a preset temperature and humidity preset value thereof. Corresponding to controlling the operation of the humidifier 38, and controlling the wind speed and the wind direction of the bladeless fan 39, so that the temperature and humidity value in the environment reaches or approaches the preset temperature and humidity preset value in the controller 31, and the temperature and humidity are preset. The set value is usually the temperature and humidity value at which the negative ions in the air are most suitable.

Moreover, in this embodiment, the humidifier 38 and the leafless fan 39 are disposed above the top of the flower pot 2 (top), so that the mist outlet of the humidifier 38 is located directly in front of the entire device, thereby when the humidifier is fogged, The mist can be directly blown into the air by the wind of the fan, so as to prevent the mist from adhering to the device and causing some safety hazards (such as leakage current). In addition, in this embodiment, the leafless fan 39 is selected so that the blades of the plant 100 are not caught in the fan blades to avoid causing the fan to block and burn the fan.

In addition, as shown in FIG. 3, the embodiment may further include an negative ion concentration detector 51 disposed on the outer casing 1 and electrically coupled to the controller 31, and detecting an negative ion concentration value in the environment and transmitting the same The controller 31, the controller 31 starts the corresponding control driving circuit 33 according to the difference between the received negative ion concentration value and the preset negative ion concentration preset value therein. Whether or not to maintain the negative ion concentration in the environment at an appropriate predetermined range. The temperature and humidity sensor 37, the humidifier 38, the leafless fan 39 and the negative ion concentration detector 51 may be collectively referred to as an negative ion space homogenizing device.

Moreover, it has been experimentally found that when the distance between the annular outer wall 11 of the outer casing 1 of the present embodiment and the flower pot 2 is between 50 mm (mm) and 200 mm (mm), as shown in FIG. 6, the first The electrode 301 and the second electrode 302 are not electrically connected to the flower pot 2 through the outer casing 1. The agave plant 100 can measure the negative ion concentration of about 50,000 ions/cm3 at a distance of about 1 meter from the outer casing 1. As shown in FIG. 7, when the first electrode 301 and the second electrode 302 are electrically connected through a wire 20 connected between the outer casing 1 and the flower pot 2, the negative ion concentration generated by the plant 100 is measured at the same distance. 3000ion/cm3, it can be seen that, in this embodiment, the flowerpot 2 is disposed in the inner chamber 121 of the outer casing 1, so that the flowerpot 2 and the outer casing 1 are separated by a distance (separated from each other), so that the first electrode 301 is not The second electrode 302 is electrically connected in a manner that allows the plant 100 to release a greater amount of negative ions, thereby effectively increasing the concentration of negative ions produced by the plant 100.

In addition, the advantage of using the negative high-pressure pulse stimulation of the agave plant in this embodiment is that the agave plant has a long time to release negative ions (ie, its life span is longer than other plants), and the agave plant is drought-tolerant. It is also shade-tolerant and easy to grow indoors. Figure 8 shows the time during which the albino agave continues to release negative ions and the concentration of negative ions released when the agave agave is continuously stimulated by a negative high-pressure pulse.

Referring to the following figure, in another embodiment of the present invention, the number of the flower pots 2 may also be two or more, that is, the embodiment and the above embodiment only One difference is that a large opening 175 is formed on the carrier tray 17' of the outer casing 1 above the inner chamber 121, and a plurality of small openings 176 are located around the large opening 175 and above the outer chamber 16, the large opening 175 A flower pot 2 for planting agave plants 100 is provided, and a small opening 176 is provided for other flower pots (not shown) for planting other plants (or agave plants).

In summary, in the above embodiment, the flower pot 2 is disposed in the inner chamber 121 of the outer casing 1 so as to be spaced apart from the annular outer wall 11 of the outer casing 1, and the first electrode 301 is in contact with the flower pot 2, and the second The electrode 302 is in contact with the outer casing 1 and spaced apart from the first electrode 301 and is not electrically connected, so that the first electrode 301 and the second electrode 302 pass through the air to form a virtual circuit, which can effectively increase the negative ion concentration generated by the plant 100, and the sense of distance is The detector 36 and the third resistor R3 are arranged to prevent electric shock (electric shock) when the object contacts the plant 100, and are provided by a temperature and humidity sensor, a humidifier, a leafless fan and a negative ion concentration detector, and The control of the controller 31 can timely adjust the negative ion concentration in the environment to maintain the negative ion concentration in the environment within an optimal range, thereby purifying the indoor air and improving the indoor air quality, thereby achieving the object and effect of the present invention.

However, the above is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention, that is, the simple equivalent changes and modifications made in accordance with the scope of the present patent application and the contents of the patent specification, All remain within the scope of this new patent.

1‧‧‧Shell

2‧‧‧ flowerpots

3‧‧‧ Negative high voltage pulse output module

4‧‧‧Remote control

31‧‧‧ Controller

32‧‧‧High speed optocoupler

33‧‧‧Drive circuit

34‧‧‧High voltage pulse generating circuit

35‧‧‧Remote signal receiving circuit

36‧‧‧Distance sensor

37‧‧‧ Temperature and Humidity Sensor

38‧‧‧Humidifier

39‧‧‧Faceless fan

51‧‧‧ Negative ion concentration detector

301‧‧‧First electrode

302‧‧‧second electrode

331‧‧‧ Half-bridge wafer

332‧‧‧MOS switch

340‧‧‧Rectifier circuit

341‧‧‧Self-recovery fuse

342‧‧‧DC power supply

T‧‧‧Step-up transformer

N1‧‧‧ primary side coil

N2‧‧‧second side coil

R1‧‧‧first resistance

R2‧‧‧second resistance

R3‧‧‧ third resistor

Claims (12)

An electric shock-proof indoor plant source negative ion surge device comprises: an outer casing comprising an annular outer wall, an annular inner wall, and a bottom plate disposed between the annular outer wall and the annular inner wall; a flower pot disposed on the outer casing An inner chamber surrounding the annular inner wall, and a bottom of the flower pot is provided with a first joint extending into the flower pot, and the bottom plate of the outer casing is provided with a second joint; a negative high voltage pulse An output module is disposed in the housing and includes: a high voltage pulse generating circuit having a first electrode electrically coupled to the first contact and a second electrode electrically coupled to the second contact a driving circuit electrically coupled to the high voltage pulse generating circuit; and a controller electrically coupled to the driving circuit and controlling the driving circuit to drive the high voltage pulse generating circuit according to an activation signal to generate a negative high voltage pulse And outputting to the first electrode; and a distance sensor electrically coupled to the controller, and outputting a control signal to the controller when detecting that an object is less than a predetermined value Based on the control signal The driving circuit stops operating system. The anti-shocking indoor plant source negative ion surge device of claim 1, wherein the negative high voltage pulse output module further comprises a high speed photocoupler electrically coupled between the controller and the drive circuit, and the controller Generating a control signal according to the start signal, and via the high speed optocoupler The controller outputs the control signal to the driving circuit to drive the high voltage pulse generating circuit to generate the negative high voltage pulse. The anti-shocking indoor plant source negative ion surge device according to claim 1, wherein the high voltage pulse generating circuit comprises a step-up transformer, a self-recovering fuse and a diode, and one end of a primary side coil of the step-up transformer is via The self-recovering fuse is electrically coupled to the DC power source, and the other end of the primary side coil is electrically coupled to the driving circuit, and one end of the primary side coil of the step-up transformer is electrically coupled to the first electrode, The other end is electrically coupled to the second electrode via the oppositely connected diode. The anti-shocking indoor plant source negative ion surge device of claim 2, wherein the negative high voltage pulse output module further comprises an electrical coupling between an output of the controller and an input of the high speed optocoupler The first resistor and one end are electrically coupled to the output end of the controller, and the other end is grounded to a second resistor. The anti-shock indoor plant source negative ion surge device of claim 1, further comprising a third resistor electrically coupled between the first electrode and the second electrode. The anti-shock indoor plant source negative ion surge device of claim 1, further comprising a temperature and humidity sensor, a humidifier and a leafless fan disposed on the outer casing and electrically coupled to the controller, the temperature The humidity sensor detects a temperature and humidity value in the environment and transmits the value to the controller, and the controller corresponds to the difference between the received temperature and humidity value and a preset temperature and humidity preset value thereof. Controlling the operation of the humidifier and the wind speed and direction of the bladeless fan. The anti-shock indoor plant source negative ion surge device of claim 1, further comprising an negative ion concentration detector disposed on the outer casing and electrically coupled to the controller, detecting an negative ion concentration value in the environment And transmitting to the controller, the controller correspondingly controls whether the driving circuit is activated or not according to the difference between the received negative ion concentration value and a predetermined negative ion concentration preset value thereof, so that the negative ion concentration is maintained at A preset range. The anti-shock indoor plant source negative ion surge device according to claim 1, further comprising a agave plant, wherein the inner basin is filled with a culture to plant the agave plant, and the first contact contacts the The culture in the inner pot transmits the negative high pressure pulse to the root of the agave plant via the culture, and stimulating the root of the agave plant causes the agave plant to release negative ions. An anti-shock, indoor plant source negative ion surge device according to claim 8, wherein the agave plant is a Phnom Penh agave. The anti-shocking indoor plant source negative ion surge device of claim 1, wherein the outer casing further comprises a carrier disk that is disposed above the annular outer wall and an outer chamber surrounded by the annular inner wall, and the carrier disk The center has a pair of openings that should be inside the chamber. The anti-shocking indoor plant source negative ion surge device of claim 10, wherein the disk surface of the carrier disk forms a plurality of perforations, and the opening periphery of the carrier disk further protrudes from a ring card corresponding to the annular inner wall. a slot, and an opening periphery of the flower pot abuts the top end of the annular card slot, so that the flower pot is suspended on the carrier tray. The anti-shocking indoor plant source negative ion surge device according to claim 10, further comprising a plurality of flower pots, and a plurality of corresponding outer chambers are formed on the disk surface of the carrier tray, and the flower pots are suspended therein. Opening.