WO2018018644A1 - System, with rain trap, for protecting against acid rain - Google Patents

Abstract

Disclosed is a system, with a rain trap (11), for protecting against acid rain, the protection system comprising a rainwater collector (1), a rainwater-monitoring meter (2), a telescopic support (3), an electric motor (4) and a canopy (5). The rainwater-monitoring meter (2) is connected to the electric motor (4). The rainwater collector (1) comprises the funnel-shaped rain trap (11) and a rainwater container (12). The rainwater container (12) is fixed to a lower end of the rain trap (11). The rainwater-monitoring meter (2) is used for detecting a characteristic value of rainwater in the rainwater collector (1), and sending a control signal to the electric motor (4) after the control signal is generated according to the characteristic value. The electric motor (4) performs corresponding operations after receiving the control signal. The telescopic support (3) is connected to the electric motor (4). The canopy (5) is fixed to the telescopic support (3). When the telescopic support (3) opens, the canopy (5) opens therewith; and when the telescopic support (3) closes, the canopy (5) closes therewith. The system, with the rain trap (11), for protecting against acid rain can control the start of the electric motor (4) so as to open the telescopic support (3) and the canopy (5) after acid rain is detected, and block the acid rain by means of the canopy (5), thus achieving the effect of protecting soil and plants under the canopy (5).

Description

Acid rain protection system with rain collector Technical field

The invention relates to the technical field of plant protection devices, in particular to an acid rain protection system with a rain collector for avoiding potted acid rain.

Background technique

The official name of acid rain is acid deposition. It refers to rain with a pH of less than 5.6. Plants usually have a high dependence on soil acidity and alkalinity and nutrients, especially potted plants. In the acid rain, the nutrients potassium, sodium, calcium and magnesium in the soil will be released and will be leached with the rain. Therefore, acid rain will cause a large amount of nutrients in the soil to be leached, resulting in serious shortage of nutrients in the soil, which will make the soil poor, which will lead to abnormal plant growth and even death.

Therefore, in order to reduce the effects of acid rain on plants and soil, it is necessary to prevent plants from coming into contact with acid rain.

Summary of the invention

In view of the deficiencies of the prior art, it is an object of the present invention to provide an acid rain protection system with a rain collector that can recognize acid rain and prevent acid rain from contacting potted plants and their soil.

To achieve the above object, the present invention adopts the following technical solutions:

An acid rain protection system with a rain collector, comprising a rainwater collector, a rainwater monitor, a telescopic bracket, a motor and a canopy; the rainwater monitor is connected with a motor; the rainwater collecting The utility model comprises a funnel-shaped rain collector and a rainwater container fixed to a lower end of the rain collector; the rain collector is configured to collect rainwater and introduce the collected rainwater into the rainwater container; the rainwater monitor is used for Detecting a characteristic value of rainwater in the rainwater collector, and transmitting a control signal to the motor, the telescopic bracket is connected to the motor after generating the control signal according to the characteristic value, and the motor drives the motor after receiving the control signal as an open signal The telescopic bracket is opened; the rain shed is fixed on the telescopic bracket; when the telescopic bracket is opened, the awning is opened; when the telescopic bracket is closed, the awning is closed;

The telescopic bracket includes a slide rail, a slider, a first telescopic assembly, a second telescopic assembly, and a transverse rod; the sliding rail is provided with a sliding slot; the slider is installed in the sliding slot, and the sliding block and the motor pass a chain connection; the first telescopic assembly is coupled to the slider and the transverse bar, the first telescopic assembly is switched between an extended state and a contracted state according to a state of the slider; the second telescopic assembly and the sliding rail And the transverse rod is fixed; the telescopic state of the second telescopic assembly is synchronized with the telescopic state of the first telescopic assembly;

The first telescopic assembly includes at least one set of telescopic rods; each of the telescopic rod sets includes two telescopic rods disposed at an intersection, and a rotating shaft is disposed at an intersection position, and the rotating shaft passes through the two telescopic rods at the same time, so that the two telescopic rods The rod can be rotated with the shaft.

Preferably, the rainwater container has a receiving cavity and an inlet, and the receiving cavity is in communication with the inlet; the inlet of the rainwater container is connected with the funnel-shaped rainwater collector outlet, and the rainwater collected by the rain collector passes through the outlet of the rain collector in turn, An inlet of the rainwater container enters the receiving chamber, and a portion of the rainwater monitor is inserted into the receiving chamber.

Preferably, the canopy is made of a flexible plastic.

Preferably, the rainwater monitor comprises a first acquisition module, a second acquisition module, and a meter Calculation module, judgment module and control module;

The first collection module generates an electromotive force after contacting the rainwater, and sends the electromotive force to the calculation module;

The second collection module is configured to detect a temperature value and a refractive index of the monitored rainwater, and send the temperature value and the refractive index to the calculation module;

The calculating module calculates the PH value of the rainwater according to the received electromotive force, the temperature value and the refractive index, and sends the PH value to the control module;

The control module generates a control signal according to the magnitude of the PH value and sends the control signal to the motor.

Preferably, the calculation module calculates the PH value of the rainwater by using the following formula:

Where: E is the electromotive force; E ⁰ is a constant; E ₂ and E ₁ are the potentials of the first acquisition module, PH ₂ and PH ₁ are the PH values of the first acquisition module; T is the temperature of the rainwater, and R is the refractive index of the rainwater , lnα(H+) is the pH value of rainwater.

Preferably, the first collection module and the second collection module are installed in the rainwater collector.

Preferably, the control module includes a receiving module, a determining module, a signal generating module, and a sending module;

The receiving module is configured to receive a PH value sent by the computing module;

The determining module is configured to determine whether the PH value received by the receiving module is less than 5.6;

The signal generating module is configured to generate the open signal when the result of the determining by the determining module is YES;

The transmitting module is configured to send the open signal to a motor.

The beneficial effects of the invention:

The acid rain protection system with the rain collector of the invention can collect the rainwater through the rainwater collector, and then collect the rainwater collected by the rainwater monitor, and control the work of the motor according to the detection result, if the detected is Acid rain can control the start of the motor to open the telescopic bracket and the canopy, and block the acid rain through the canopy to protect the soil and plants under the canopy. Moreover, the rainwater collector collects the rainwater through a funnel-shaped rain collector, and then the rainwater container receives the rainwater, so that the rainwater collector can collect the rainwater.

DRAWINGS

1 is a schematic structural view of an acid rain protection system with a rain collector according to an embodiment of the present invention;

2 is a schematic view showing the installation of a rain canopy and a telescopic bracket according to an embodiment of the present invention;

3 is a schematic structural view of a rainwater collector according to an embodiment of the present invention;

4 is a block diagram of a rainwater monitor in an embodiment of the present invention;

FIG. 5 is a schematic diagram of a first acquisition module according to an embodiment of the present invention.

In the figure: 1, rainwater collector; 10, housing cavity; 11, rain collector; 12, rainwater container; 2, rainwater monitor; 21, first acquisition module; 211, protective shell; 212, first test body; 2121, a first housing; 2122, a first detection solution; 2123, a first electrode guide 213, second detecting body; 2131, second housing; 2132, second detecting solution; 2133, second electrode lead; 22, second collecting module; 23, calculating module; 24, control module; Module; 242, judgment module; 243, signal generation module; 244, transmission module; 3, telescopic support; 31, slide rail; 310, chute; 32, slider; 33, first telescopic assembly; Rod; 332, shaft; 34, second telescopic assembly; 341, second telescopic rod; 3411, hollow tube; 35, transverse rod; 4, motor;

detailed description

The present invention will be further described below in conjunction with the drawings and specific embodiments.

Referring to Figures 1 and 2, the present invention relates to an acid rain protection system with a rain collector, including a rainwater collector 1, a rainwater monitor 2, a telescopic support 3, a motor 4, and a canopy 5. The rainwater monitor 2 is connected to the motor 4. The rainwater monitor 2 is for detecting a characteristic value of rainwater in the rainwater collector 1, and transmits a control signal to the motor 4 after generating a control signal based on the characteristic value. The characteristic value includes a temperature value of rain water, a refractive index or a pH value, and the like. The motor 4 performs a corresponding operation after receiving the control signal. The control signal can be an open signal that controls the activation of the motor 4. For example, when the motor 4 receives the start control signal, the motor 4 performs a start-up operation, that is, starts working to open the telescopic bracket 3.

The telescopic bracket 3 is connected to the motor 4, and the telescopic bracket 3 is controlled to switch between an open state and a collapsed state by the motor 4. The closing of the motor 4 can be manually closed. Of course, the telescopic support 3 can also be closed manually. The canopy 5 is fixed to the telescopic support 3. When the telescopic stand 3 is opened, the canopy 4 is opened. When the telescopic support 3 is gathered, the canopy 5 is gathered. The canopy 5 is used to block rain. Normally, when the rainwater monitor 2 detects that the rainwater is acid rain, the control signal for starting the motor 4 is sent. The motor 4 is caused to work to open the telescopic bracket 3, so that the canopy 5 is opened to prevent acid rain from coming into contact with the soil and plants under the canopy 5, thereby realizing the effect of protecting plants and soil. The rain, 5 is made of flexible plastic. Therefore, the canopy 5 can be opened and contracted simultaneously with the opening and contraction of the telescopic bracket 3.

Referring to Figure 3, the rainwater collector 1 defines a receiving chamber 10 for collecting rainwater. A portion of the rainwater monitor 2 is inserted into the accommodating chamber 10. Specifically, at least the rainwater component detected by the rainwater monitor 2 can be inserted into the accommodating chamber 10. The rainwater collector 1 is placed outdoors when it is necessary to detect whether there is acid rain. Since the rainwater collector 1 is for collecting rainwater that naturally falls, the accommodating chamber 10 is open toward the sky so that rainwater falls into the accommodating chamber 10. The rainwater is collected through the accommodating chamber 10 so that the rainwater monitor 2 is better in contact with the rainwater, thereby improving the detection efficiency.

The rainwater collector 1 includes a funnel-shaped rain collector 11 and a rainwater container 12 fixed to a lower end of the rain collector 11; the rain collector 11 is for collecting rainwater and introducing the collected rainwater Inside the rainwater container 12. The rainwater monitor 3 is specifically used to detect the characteristic value of the rainwater in the rainwater container 12. The rainwater container 12 defines a receiving chamber 10 and an inlet (not shown), and the receiving chamber 10 communicates with the inlet; the inlet of the rainwater container 12 communicates with the outlet of the funnel-shaped rain collector 11, and the collecting device 11 collects Rainwater enters the accommodating chamber 10 through the outlet of the sump 11 and the inlet of the rainwater container 12, and a portion of the first collection module 2 is inserted into the accommodating chamber 10.

Referring to FIG. 4, the rainwater monitor 2 includes a first acquisition module 21, a second acquisition module 22, a calculation module 23, and a control module 24. The first collection module 21 generates an electromotive force after contacting the rainwater, and sends the electromotive force to the calculation module 23. First acquisition module 21 includes a measuring electrode and a reference electrode, the measuring electrode being an electrode selective for hydrogen ions. Therefore, when the first collection module 21 is inserted into the rainwater to be measured, a corresponding electromotive force can be generated according to the pH of the rainwater. The calculation module 23 and the control module 24 can be combined into a part of the module of the single chip microcomputer. The second collection module 22 can be a temperature sensor and a refractometer.

Referring to FIG. 5 , the first collection module 21 includes a protective shell 211 and a first detecting body 212 and a second detecting body 213 installed in the protective casing 211 . A cavity for mounting the first detecting body 212 and the second detecting body 213 is opened in the protective casing 211. The first detecting body 212 includes a first housing 2121, a first detecting solution 2122, and a first electrode lead 2123. The first housing 2121 is hollow inside. The first detecting liquid 2122 is received in the first housing 2121. One end of the first electrode lead 2123 is immersed in the first detecting solution 2122, and the other end passes through the first housing 2121 and the protective case 211 in sequence and is connected to the calculation module 23. The first detecting body 212 is not in contact with the rain water to be detected during the measurement; and the second detecting body 213 is in contact with the rain water to be detected.

The second detecting body 213 includes a second housing 2131, a second detecting solution 2132, and a second electrode lead 2133. The second housing 2131 is hollow inside. The second detecting liquid 2132 is received in the second housing 2131. One end of the second electrode lead 2133 is immersed in the second detecting solution 2132, and the other end passes through the second housing 2131 and the protective case 211 in sequence and is connected to the calculation module 23.

The first housing 2121 and the second housing 2131 are each made of glass. The first detection solution 2122 and the second detection solution 2132 are both potassium chloride solutions having a concentration of about 3 mol/L, wherein the first detection solution 2122 occupies about 1\9-1\51 of the internal space of the first housing 2121. ; The second detection solution 2132 occupies about 1\9-1\51 of the internal space of the second casing 2131. The first electrode lead 2123 and the second electrode lead 2133 may be silver chloride.

The second collection module 22 is configured to detect a temperature value and a refractive index of the monitored rainwater, and send the temperature value and the refractive index to the calculation module 23. The calculation module 23 calculates the PH value of the rainwater based on the received electromotive force, temperature value, and refractive index, and sends it to the control module 24. The control module 24 generates a control signal according to the magnitude of the PH value and transmits the control signal to the motor 4. The second collection module 22 can be a refractometer or refractometer.

The calculation module 23 can be a calculator, and the calculation module 23 calculates the PH value of the rainwater by using the following formula (1)(2):

Wherein: E is an electromotive force; E ⁰ is less than or equal to an E constant; and E ₂ and E ₁ are potentials of the first detection solution 2122 and the second detection solution 2132 in the first acquisition module 21, respectively, and PH ₂ and PH ₁ are The pH of the first detection solution 2122 and the second detection solution 2132 in the acquisition module 21; T is the temperature of the rainwater, R is the refractive index of the rainwater; and lnα(H ⁺ ) is the pH value of the rainwater. The accuracy of the rainwater monitor 2 can be effectively improved by collecting the temperature value and the refractive index of the rainwater by setting the second collection module 22 in the rainwater monitor 2. lgR represents the logarithm of base 10, and lnα(H ⁺ ) represents the logarithm of e.

The first collection module 21 and the second collection module 22 are installed in the rainwater collector 1 . Specifically, the first collection module 21 and the second collection module 22 are installed in the accommodating cavity 10 to be in contact with the rainwater to be tested.

The control module 24 includes a receiving module 241, a determining module 242, a signal generating module 243, and a sending module 244. The receiving module 241 is configured to receive the PH value sent by the computing module 23. The determining module 242 is configured to determine whether the PH value received by the receiving module 241 is less than 5.6. If yes, the rainwater is acid rain, and the rain canopy needs to be opened, otherwise the canopy may not be opened. The signal generating module 243 is configured to generate an open signal for turning on the motor 4 when the result of the determining module determining 242 is YES. The sending module 244 is configured to send an open signal of the open motor 4 to the motor 4.

The motor 4 is started after receiving the opening signal of the opening motor 4, and drives the telescopic bracket 3 to open, thereby opening the canopy 5. When there is a plant under the canopy 5, the rainwater can be blocked by the open canopy 5 to prevent rainwater from coming into contact with the plants.

The telescopic bracket 3 includes a slide rail 31, a slider 32, a first telescopic assembly 33, a second telescopic assembly 34, and a transverse rod 35. A sliding slot 310 is defined on the sliding rail 31. The slider 32 is mounted in a chute 310 that is coupled to the motor 4 by a chain. Since the canopy 5 is made of a flexible plastic having a waterproof effect, the canopy 5 can be supported by two telescopic components to prevent excessive accumulation of rain on the canopy 5, thereby effectively improving the durability of the canopy 5. The slider 32 can be driven by the motor 5 to slide on the chute 310. The transverse bar 35 is arranged in parallel with the slide rail 31. The first telescopic assembly 33 is coupled to both the slider 32 and the transverse bar 35. The first telescopic assembly 33 is switched between an extended state and a contracted state according to the state of the slider 32. The expansion and contraction state of the first telescopic assembly 33 is described when the slider 32 is two. When the two sliders 32 are close to each other, the first telescopic assembly 33 is fully opened. The linear distance between the transverse rod 35 and the slide rail 31 is the largest; when the linear distance between the two sliders 32 is gradually increased, the first telescopic assembly 33 is realized. Gradually, the distance between the transverse bar 35 and the slide rail 31 is gradually shortened. The second telescopic assembly 34 is fixed to the slide rail 31 and the transverse rod 35.

The first telescopic assembly 33 includes at least one set of telescopic rods; each of the telescopic rod sets includes two first telescopic rods 331 disposed at an intersection, and a rotating shaft 332 is disposed at an intersecting position, and the rotating shaft 332 passes through two A telescopic rod 331 enables the two first telescopic rods 331 to rotate with the rotating shaft 332. When the two first telescopic rods 331 are rotated about the rotation shaft 332, the angle between the two first telescopic rods 331 is changed, and the first telescopic assembly 33 is elongated and shortened. With reference to FIG. 1 , the telescopic rod set is two sets, each telescopic rod set includes four first telescopic rods 331 , and two first telescopic rods 331 disposed in a pair are a pair, and the two pairs of first telescopic rods 331 are mutually Handover.

The telescopic state of the second telescopic assembly 34 is synchronized with the telescopic state of the first telescopic assembly 33. The second telescopic assembly 34 includes two second telescopic rods 341, each of the second telescopic rods 341 includes at least two hollow tubes 3411, and the two hollow tubes 3411 have different diameters, and the small diameter hollow tubes 3411 can be inserted in the In the large-diameter hollow tube 3411, when there is external force pushing and pulling, the small-diameter hollow tube 3411 can be extended or retracted in the large-diameter hollow tube 3411, thereby realizing the elongation of the second telescopic rod 341. shorten. In Fig. 1, each of the second telescopic rods 341 includes three hollow tubes 3411.

In summary, the acid rain protection system with the rain collector of the present invention can collect rainwater through the rainwater collector 1, and then collect the collected rainwater through the rainwater monitor 2, and control the work of the motor 4 according to the detection result. If the detected acid rain can control the motor 4 to start, the telescopic support 3 and the canopy 5 are opened, and the acid rain is blocked by the canopy 5 to achieve the effect of protecting the soil and plants under the canopy 5.

Various other changes and modifications may be made by those skilled in the art in light of the above-described technical solutions and concepts, and all such changes and modifications are intended to fall within the scope of the appended claims.

Claims (7)

1. An acid rain protection system with a rain collector, comprising: a rainwater collector, a rainwater monitor, a telescopic support, a motor and a canopy; the rainwater monitor is connected with a motor; the rainwater collector comprises a funnel shape a rain collector and a rainwater container fixed to a lower end of the rain collector; the rain collector is configured to collect rainwater and introduce the collected rainwater into the rainwater container; the rainwater monitor is used for detecting the rainwater collector a characteristic value of the rainwater, and after the control signal is generated according to the characteristic value, sending a control signal to the motor, the telescopic bracket is connected to the motor, and the motor drives the telescopic bracket to open after receiving the control signal as an open signal; The canopy is fixed on the telescopic support; when the telescopic support is opened, the canopy is opened; when the telescopic support is closed, the canopy is closed;

   The telescopic bracket includes a slide rail, a slider, a first telescopic assembly, a second telescopic assembly, and a transverse rod; the sliding rail is provided with a sliding slot; the slider is installed in the sliding slot, and the sliding block and the motor pass a chain connection; the first telescopic assembly is coupled to the slider and the transverse bar, the first telescopic assembly is switched between an extended state and a contracted state according to a state of the slider; the second telescopic assembly and the sliding rail And the transverse rod is fixed; the telescopic state of the second telescopic assembly is synchronized with the telescopic state of the first telescopic assembly;

   The first telescopic assembly includes at least one set of telescopic rods; each of the telescopic rod sets includes two telescopic rods disposed at an intersection, and a rotating shaft is disposed at an intersection position, and the rotating shaft passes through the two telescopic rods at the same time, so that the two telescopic rods The rod can be rotated with the shaft.
2. The acid rain protection system with a rain collector according to claim 1, wherein the rainwater container has a receiving chamber and an inlet, the receiving chamber is in communication with the inlet; the inlet of the rainwater container and the funnel-shaped rain collector The outlet is connected to communicate with the rainwater collected by the rain collector through the outlet of the rain collector and the inlet of the rainwater container into the receiving chamber, the rainwater A portion of the monitor is inserted into the receiving cavity.
3. The acid rain protection system with a rain collector according to claim 1, wherein the canopy is made of a flexible plastic.
4. The acid rain protection system with a rain collector according to any one of claims 1 to 3, wherein the rainwater monitor comprises a first acquisition module, a second acquisition module, a calculation module, a determination module and a control module;

   The first collection module generates an electromotive force after contacting the rainwater, and sends the electromotive force to the calculation module;

   The second collection module is configured to detect a temperature value and a refractive index of the monitored rainwater, and send the temperature value and the refractive index to the calculation module;

   The calculating module calculates the PH value of the rainwater according to the received electromotive force, the temperature value and the refractive index, and sends the PH value to the control module;

   The control module generates a control signal according to the magnitude of the PH value and sends the control signal to the motor.
5. The acid rain protection system with a rain collector according to claim 4, wherein the calculation module calculates the PH value of the rainwater by using the following formula:

   

   

   Where: E is the electromotive force; E ⁰ is a constant; E ₂ and E ₁ are the potentials of the first acquisition module, PH ₂ and PH ₁ are the PH values of the first acquisition module; T is the temperature of the rainwater, and R is the refractive index of the rainwater , lnα(H+) is the pH value of rainwater.
6. The acid rain protection system with a rain collector according to claim 5, wherein the first collection module and the second collection module are installed in the rainwater collector.
7. The acid rain protection system with a rain collector according to claim 5, wherein the control module comprises a receiving module, a determining module, a signal generating module and a transmitting module;

   The receiving module is configured to receive a PH value sent by the computing module;

   The determining module is configured to determine whether the PH value received by the receiving module is less than 5.6;

   The signal generating module is configured to generate the open signal when the result of the determining by the determining module is YES;

   The transmitting module is configured to send the open signal to a motor.

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