CN117783490A - Soil moisture content acquisition monitoring device - Google Patents

Abstract

The invention relates to the field of detection instruments, in particular to a soil moisture content acquisition and monitoring device which comprises a detection instrument, an electric control cabinet, a partition board, an air suction pipe, a dehumidifying chamber and a dehumidifying mechanism. When the humidity degree in the lower mounting cavity reaches a preset value, starting the air suction assembly, enabling air in the lower mounting cavity to enter the air suction pipe and flow into the sleeve, enabling air to flow into the spherical shell through the air transmission hole on the sleeve and contact with the dehumidifying ball in the spherical shell, and dehumidifying the air; the dehumidified air returns to the lower mounting cavity through the air return assembly, so that the air in the lower mounting cavity is prevented from damaging the circuit board, the connecting wire and the storage battery due to moisture; when the dehumidifying ball cannot dehumidify the air, the dehumidifying ball is dried through the drying assembly; the dehumidifying ball can be recycled, and the replacement work of the dehumidifying ball is reduced. The problem of among the prior art when having moist moisture in the equipment box is direct through long-time use heating device and dry fan to cause the extravagant energy is solved.

Description

Soil moisture content acquisition monitoring device

Technical Field

The invention relates to the field of detection instruments, in particular to a soil moisture content acquisition and monitoring device.

Background

The soil moisture content collecting and monitoring device is a machine commonly used for detecting soil moisture content, and the soil moisture content collecting and monitoring device is used for sampling soil and then detecting the soil; the soil moisture refers to the humidity of the soil suitable for plant growth and development. Soil moisture refers to the condition of soil humidity.

The electric control cabinet of the soil moisture content monitoring instrument in the prior art has no moisture-proof function, so that the circuit board, the connecting wire and the storage battery inside the electric control cabinet are easy to be wet in the outdoor long-time use process, and damage is caused to the electric control cabinet.

In the prior art, such as the document with the authorized publication number CN218896112U, the moist air in the pinnacle rain-proof box can be absorbed by placing a moisture-absorbing cotton board in a rack, keeping the interior dry. However, when the absorbent cotton of the absorbent assembly is wet, the absorbent cotton cannot work any more, and the absorbent cotton has limited drying capacity and cannot work for a long time. Such as the document of the authorized publication number CN214703618U, when the moisture detector detects that the interior of the equipment box contains moisture, the heating device and the drying fan are started, so that the heating device can heat the wind power of the drying fan, so that the drying fan can dry the interior of the equipment box, and so that the internal detection device can remain dry. The direct use of the heating equipment and the drying fan can enable the electric control cabinet to be kept dry in a short time, but is not suitable for long-time work, the consumption of the storage battery is easy to increase, and the cruising ability of the soil moisture content collecting and monitoring device is greatly reduced.

Disclosure of Invention

The invention provides a soil moisture content collecting and monitoring device, which solves the problems that a dehumidifying part cannot work for a long time and needs to be replaced frequently, and when moisture exists in an equipment box, the dehumidifying part is not used, and a heating device and a drying fan are directly used for a long time, so that energy is wasted.

The invention relates to a soil moisture content acquisition and monitoring device which adopts the following technical scheme: the soil moisture content collecting and monitoring device comprises a detecting instrument, an electric control cabinet, a partition board, an air suction pipe, a dehumidifying chamber, N dehumidifying mechanisms, N diversion mechanisms and N groups of adjusting mechanisms.

The baffle level sets up in automatically controlled cabinet, and the baffle is last installation cavity and lower installation cavity with the internal partition of automatically controlled cabinet, and the circuit is all installed in lower installation cavity.

The air suction pipe is vertically arranged on the partition board and can rotate around the axis of the air suction pipe, the upper end of the air suction pipe is positioned in the upper mounting cavity, and the lower end of the air suction pipe penetrates through the partition board and extends to the lower mounting cavity; designating an axis near the air suction pipe as an inner side along the radial direction of the air suction pipe; the axis far away from the air suction pipe is the outer side; the air suction pipe is connected with an air suction component so that air in the lower mounting cavity enters the air suction pipe when the humidity degree in the lower mounting cavity reaches a preset value.

The dehumidifying chamber is horizontally arranged in the upper mounting cavity, extends along the radial direction of the air suction pipe, and is fixedly connected with the air suction pipe, and the inside of the dehumidifying chamber is hollow; the dehumidifying chamber is connected with an air return assembly which is communicated with the dehumidifying chamber and the lower mounting cavity; the dehumidifying chamber is provided with a drying component for drying the dehumidifying balls.

The N dehumidification mechanisms are distributed along the axial direction of the dehumidification chamber; the dehumidifying mechanism comprises a spherical shell and a sleeve; the sleeve is coaxially arranged in the dehumidifying chamber, and can rotate relative to the dehumidifying chamber; one end of the innermost sleeve, which faces the axis of the air suction pipe, is communicated with the air suction pipe; one end of the outermost sleeve, which is far away from the axis of the air suction pipe, is closed; the side wall of the sleeve is provided with a plurality of gas transmission holes; the ball shell is sleeved on the sleeve and positioned outside the gas transmission hole; the ball shell is internally provided with a containing cavity which can contain the dehumidifying ball; the side wall of the spherical shell is provided with a plurality of through holes.

The N diversion mechanisms are respectively and correspondingly arranged in the N sleeves and are opposite to the gas transmission holes on the sleeves; the air guide mechanism is in a retracted state and an extended state, and when the air guide mechanism is in the extended state, air in the sleeve can be guided to the air transmission hole on the corresponding sleeve and the corresponding sleeve is driven to rotate; when the flow guiding mechanism is in a retracted state, guiding air to axially move along the sleeve; a connecting shaft is arranged in the dehumidifying chamber, is fixedly connected to the air suction pipe and radially extends along the air suction pipe; the guide mechanism comprises a slide tube and a plurality of guide plates, and the slide tube can axially move and is rotatably sleeved on the connecting shaft and is opposite to the gas transmission hole; the guide plates are positioned between the slide tube and the sleeve and are uniformly distributed along the circumference of the slide tube; the two ends of the guide plate are respectively connected with the slide tube and the sleeve, one end of the guide plate is rotatably arranged on the sleeve, and the other end of the guide plate is connected with the slide tube; a plurality of stirring plates with hollow structures are fixedly connected to the peripheral wall of the sleeve, each stirring plate corresponds to one gas transmission hole, and a plurality of through holes are formed in the stirring plates.

The N groups of adjusting mechanisms respectively correspond to the N diversion mechanisms, and the adjusting mechanisms are configured to enable the diversion mechanisms in the spherical shell to be adjusted from an unfolding state to a folding state when the dehumidifying balls in the spherical shell cannot dehumidify; each group of adjusting mechanisms comprises a plurality of adjusting mechanisms, and the plurality of adjusting mechanisms of each group are respectively and correspondingly arranged on a plurality of guide plates arranged on one slide tube; the adjusting mechanism comprises a chute, a groove and a limiting lug; the sliding groove extends along the axial direction of the connecting shaft and is arranged on the inner wall of the sleeve; the groove is arranged at the outer side of the chute and is communicated with the chute, the distance between the groove and the axis of the slide tube is larger than the distance between the chute and the axis of the slide tube, the limit lug is arranged at one end of the guide plate, which is far away from the axis of the slide tube, and the limit lug is slidably arranged in the chute and the groove; the guide plate is provided with a connecting column at one end facing the slide tube, the connecting column is inserted on the slide tube, a pressure spring is connected between the guide plate and the slide tube, and the pressure spring has a trend of enabling the connecting column to be far away from the axis of the slide tube; the connecting column is in threaded fit with the slide tube.

Further, the dehumidifying chamber is uniformly distributed with a plurality of dehumidifying chambers along the circumferential direction of the air suction pipe.

Further, a plurality of drying stations are arranged in each dehumidification chamber at intervals, and the number of the drying stations is consistent with that of the spherical shells; the spherical shell and the slide tube synchronously move horizontally, and the spherical shell can rotate around the axis of the slide tube only when in the drying station; a plurality of bulges are fixedly arranged on the connecting shaft and are positioned in the drying station; the drying assembly comprises a plurality of unidirectional pipes which are arranged in the dehumidifying chamber and correspond to the drying stations one by one; a heating component is arranged in each unidirectional pipe; reset components are arranged in each dehumidification chamber; the air exhaust assembly is communicated with the plurality of dehumidifying chambers and the atmosphere.

Further, the reset assembly includes a first spring and a plurality of second springs; the first spring is sleeved outside the sleeve, one end of the first spring is connected with the innermost spherical shell, and the other end of the first spring is connected with the dehumidifying chamber; the second springs are sleeved outside the connecting shaft and correspond to the sliding pipes one by one, one ends of the second springs are connected to the sliding pipes, and the other ends of the second springs are connected to adjacent bulges of the sliding pipes.

Further, the exhaust assembly comprises a solenoid valve and a main exhaust pipe; a dehumidifying exhaust pipe is connected above the drying station, is communicated with a main exhaust pipe, extends out of an upper mounting cavity above the main exhaust pipe and is connected with the atmosphere; the solenoid valve is installed on the main exhaust pipe.

Further, the air return assembly comprises a cover plate, an air return chamber, an air return pipe and a connecting pipe; the air return chamber is fixedly arranged on the partition board; the cover plate is rotatably arranged in the air return chamber, and the air return chamber and the cover plate define an air return chamber; the connecting pipe is communicated with the outer end of the dehumidifying chamber and the air return cavity; the air return pipe is communicated with the air return cavity and the lower mounting cavity.

Further, a plurality of air return pipes are arranged and uniformly distributed on the periphery of the air suction pipe along the circumferential direction of the air suction pipe.

The beneficial effects of the invention are as follows: when the humidity degree in the lower mounting cavity reaches a preset value, starting the air suction assembly, enabling air in the lower mounting cavity to enter the air suction pipe and flow into the sleeve, enabling air to flow into the spherical shell through the air transmission hole on the sleeve and contact with the dehumidifying ball in the spherical shell, and dehumidifying the air; the dehumidified air returns to the lower mounting cavity through the air return assembly, so that the air in the lower mounting cavity is prevented from damaging the circuit board, the connecting wire and the storage battery due to moisture; when the dehumidifying ball cannot dehumidify the air, the dehumidifying ball is dried through the drying assembly; the dehumidifying ball can be recycled, and the replacement work of the dehumidifying ball is reduced. The problem of among the prior art when having moist moisture in the equipment box is direct through long-time use heating device and dry fan to cause the extravagant energy is solved.

Further, by arranging a plurality of dehumidification chambers and a plurality of dehumidification mechanisms in the same dehumidification chamber, the progress of dehumidification work is quickened, and the dehumidification efficiency is improved. The air guiding mechanism and the adjusting mechanism are arranged, so that moist air is dehumidified in the spherical shells positioned in the same dehumidifying chamber in turn from inside to outside, and the power of gas flow is reasonably distributed on the corresponding guide plates; the stirring assembly is guaranteed to have proper rotation power, the stirring effect is guaranteed, and the phenomenon that the wetted dehumidifying ball affects the gas again can be avoided.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions of the prior art, the drawings which are used in the description of the embodiments or the prior art will be briefly described, it being obvious that the drawings in the description below are only some embodiments of the invention, and that other drawings can be obtained according to these drawings without inventive faculty for a person skilled in the art.

FIG. 1 is a schematic view of a soil moisture content collection and monitoring device according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of an electric control cabinet in an embodiment of a soil moisture content collecting and monitoring device according to the present invention;

FIG. 3 is a cross-sectional view taken along section A-A of FIG. 2;

FIG. 4 is an enlarged view of a portion of the portion X of FIG. 3;

FIG. 5 is a schematic view showing a state that an annular friction plate is positioned in a dehumidifying station in an embodiment of a soil moisture content collecting and monitoring device of the present invention;

FIG. 6 is an enlarged view of a portion of the portion of FIG. 4 at Y;

FIG. 7 is a schematic diagram of an explosion of a dehumidification mechanism in an embodiment of a soil moisture content collection and monitoring device of the present invention;

FIG. 8 is an exploded view of the spherical shell and the internal structure of the soil moisture content collection and monitoring device according to the embodiment of the invention;

fig. 9 is a schematic structural view of a spherical shell in an embodiment of a soil moisture content collecting and monitoring device according to the present invention;

fig. 10 is a schematic structural view of a slide tube in an embodiment of a soil moisture content collecting and monitoring device according to the present invention;

FIG. 11 is a schematic view illustrating installation of a deflector and a slide tube in an embodiment of a soil moisture content collection and monitoring device according to the present invention;

fig. 12 is a schematic view showing an initial state of a deflector in an embodiment of a soil moisture content collecting and monitoring device according to the present invention;

fig. 13 is a schematic view of a state when a deflector is parallel to a sliding tube axis in an embodiment of a soil moisture content collection and monitoring device of the present invention.

In the figure: 100. a detection instrument; 200. a solar cell panel; 300. an electric control cabinet; 301. a partition plate; 400. a main exhaust pipe; 401. an electromagnetic valve; 500. a cover plate; 600. an air return assembly; 601. an air return pipe; 700. a dehumidifying mechanism; 701. an air suction pipe; 702. a dehumidifying station; 703. a drying station; 704. a connecting pipe; 705. a dehumidifying exhaust pipe; 706. a unidirectional tube; 707. a vent pipe; 800. a spherical shell; 801. a first spring; 802. an annular friction plate; 803. a guide plate; 804. an inner sleeve; 900. a sleeve; 901. a chute; 902. a groove; 903. a stirring plate; 904. a gas transmission ring; 110. a connecting shaft; 111. a protrusion; 120. a slide tube; 121. a connection hole; 122. a second spring; 130. a deflector; 131. a connecting column; 1311. a spiral groove; 132. and a limit bump.

Detailed Description

Reference will now be made in detail to the present embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the like or similar elements throughout or elements having the same or similar functions. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The features of the invention "first", "second" and the like in the description and in the claims may be used for the explicit or implicit inclusion of one or more such features. In the description of the present invention, unless otherwise indicated, the meaning of "a plurality" is two or more.

In the description of the present invention, it should be understood that the terms "center", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "circumferential", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present invention will be understood in specific cases by those of ordinary skill in the art.

An embodiment of a soil moisture content collection and monitoring device of the present invention is shown in fig. 1 to 13: the device comprises a detecting instrument 100, an electric control cabinet 300, a partition 301, an air suction pipe 701, a dehumidifying chamber, N dehumidifying mechanisms 700, N diversion mechanisms and N groups of adjusting mechanisms, wherein N is greater than or equal to 1.

The baffle 301 is horizontally arranged on the electric control cabinet 300, the baffle 301 divides the interior of the electric control cabinet 300 into an upper mounting cavity and a lower mounting cavity, and the circuits are all arranged in the lower mounting cavity.

The air suction pipe 701 is vertically arranged on the partition 301 and can rotate around the axis of the air suction pipe, the upper end of the air suction pipe is positioned in the upper mounting cavity, and the lower end of the air suction pipe penetrates through the partition 301 and extends to the lower mounting cavity; designating an axis near the suction pipe 701 as an inner side in a radial direction of the suction pipe 701; the axis far away from the air suction pipe 701 is the outer side; the air suction pipe 701 is connected with an air suction component so that when the humidity degree in the lower mounting cavity reaches a preset value, the air in the lower mounting cavity enters the air suction pipe 701; the suction assembly includes a humidity sensor and a suction pump that introduces the gas in the lower mounting chamber into the suction pipe 701 when the humidity sensor detects that the humidity in the lower mounting chamber reaches a preset value.

The dehumidifying chamber is horizontally arranged in the upper mounting cavity, extends along the radial direction of the air suction pipe 701, is fixedly connected with the air suction pipe 701, and is hollow inside; the dehumidifying chamber is connected with an air return assembly 600, and the air return assembly 600 is communicated with the dehumidifying chamber and the lower mounting cavity; a drying component for drying the dehumidifying balls is arranged on the dehumidifying chamber; the connection between the dehumidifying chamber and the suction pipe 701 is connected by a ventilation pipe 707.

The N dehumidifying mechanisms 700 are distributed along the axial direction of the dehumidifying chamber; the dehumidifying mechanism 700 includes a spherical shell 800 and a sleeve 900; the sleeve 900 is coaxially arranged in the dehumidifying chamber, and the sleeve 900 can rotate relative to the dehumidifying chamber; one end of the innermost sleeve 900 facing the axis of the air suction pipe 701 is inserted into the air vent pipe 707 and is communicated with the air suction pipe 701; the end of the outermost sleeve 900 remote from the axis of the suction pipe 701 is closed; one or more dehumidifying mechanisms 700 can be provided, when one dehumidifying mechanism 700 is provided, one sleeve 900 is provided, and the inner end of the sleeve 900 is communicated with the air suction pipe 701, and the outer end is in a closed state; when the dehumidifying mechanism 700 is multiple, the multiple sleeves 900 are coaxially arranged, and two adjacent sleeves 900 can rotate relatively, and one end of the innermost sleeve 900, which faces the axis of the air suction pipe 701, is communicated with the air suction pipe 701; the end of the outermost sleeve 900 remote from the axis of the suction pipe 701 is closed; a plurality of gas transmission holes are uniformly distributed on the side wall of the sleeve 900 along the circumferential direction; the spherical shell 800 is sleeved on the sleeve 900 and is positioned outside the gas transmission hole; the bulb 800 has a receiving cavity inside to be able to receive the dehumidifying bulb; the sidewall of the bulb 800 is provided with a plurality of through holes.

The N diversion mechanisms are respectively and correspondingly arranged in the N sleeves 900 and are opposite to the gas transmission holes on the sleeves 900; the flow guide mechanism has a retracted state and an extended state, and when the flow guide mechanism is in the extended state, air in the sleeve 900 can be guided to the air transmission hole on the corresponding sleeve 900 and the corresponding sleeve 900 is driven to rotate; when the flow guiding mechanism is in a retracted state, guiding air to axially move along the sleeve 900; a connecting shaft 110 is arranged in the dehumidifying chamber, and the connecting shaft 110 is fixedly connected with the air suction pipe 701 and extends along the radial direction of the air suction pipe 701; the flow guiding mechanism comprises a sliding tube 120 and a plurality of flow guiding plates 130, wherein the sliding tube 120 can axially move and is rotatably sleeved on the connecting shaft 110 and is opposite to the gas transmission hole; the guide plates 130 are positioned between the slide tube 120 and the sleeve 900 and are uniformly distributed along the circumference of the slide tube 120; the two ends of the guide plate 130 are respectively connected with the slide tube 120 and the sleeve 900, one end of the guide plate 130 is rotatably arranged on the sleeve 900, and the other end is connected with the slide tube 120; a plurality of stirring plates 903 with hollow structures are fixedly connected to the peripheral wall of the sleeve 900, each stirring plate 903 corresponds to one gas transmission hole, and a plurality of through holes are formed in the stirring plate 903.

The N groups of adjusting mechanisms respectively correspond to the N diversion mechanisms, and the adjusting mechanisms are configured to enable the diversion mechanisms in the spherical shell 800 to be adjusted from an unfolding state to a folding state when the dehumidifying balls in the spherical shell 800 cannot dehumidify; each group of adjusting mechanisms comprises a plurality of adjusting mechanisms, and the plurality of adjusting mechanisms of each group are respectively and correspondingly arranged on a plurality of guide plates 130 arranged on one slide tube 120; the adjusting mechanism comprises a chute 901, a groove 902 and a limit bump 132; the sliding groove 901 extends along the axial direction of the connecting shaft 110 and is arranged on the inner wall of the sleeve 900, and the length of the sliding groove 901 is longer than that of the groove 902; the groove 902 is arranged on the outer side of the chute 901 and is communicated with the chute 901, the distance between the groove 902 and the axis of the slide tube 120 is larger than the distance between the chute 901 and the axis of the slide tube 120, and the connecting position of the chute 901 and the groove 902 is smooth; the limiting lug 132 is arranged at one end of the guide plate 130 far away from the axis of the slide tube 120, and the limiting lug 132 is slidably arranged in the chute 901 and the groove 902; a connecting column 131 is arranged at one end of the guide plate 130 facing the slide tube 120, a connecting hole 121 is formed in the slide tube 120 at a corresponding position, and the connecting column 131 is inserted into the connecting hole 121; the connecting column 131 is provided with a spiral groove 1311, the connecting hole 121 is fixedly provided with a convex column, and the convex column is slidably arranged in the spiral groove 1311; a compression spring is connected between the end of the connecting post 131 facing the slide tube 120 and the slide tube 120, and in an initial state, the compression spring tends to keep the connecting post 131 away from the axis of the slide tube 120.

When the humidity sensor detects that the humidity degree in the lower mounting cavity reaches a preset value, the air suction pump enables air in the lower mounting cavity to enter the air suction pipe 701 and flow into the sleeve 900, and air flows into the spherical shell 800 through the air transmission holes on the sleeve 900 and contacts with the dehumidifying balls in the spherical shell 800 to dehumidify the air; the dehumidified air is returned to the lower installation cavity through the air return assembly 600, thereby ensuring that the air in the lower installation cavity does not damage the circuit board, the connecting wires and the battery due to moisture; when the dehumidifying ball cannot dehumidify the air, the dehumidifying ball is dried through the drying assembly; the dehumidifying ball can be recycled, and the replacement work of the dehumidifying ball is reduced. The problem of among the prior art when having moist moisture in the equipment box is direct through long-time use heating device and dry fan to cause the extravagant energy is solved.

When the flowing air flows through the innermost guide mechanism and the guide mechanism is in an unfolded state, as shown in fig. 12, an included angle exists between the projection of the guide plate 130 on the horizontal plane and the axis of the slide tube 120; the air acts on the deflector 130 to rotate the deflector 130 around the axis of the connecting shaft 110, and the other small force moves the deflector 130 to the outside by a preset distance, but the length of the chute 901 is greater than that of the groove 902, so that the limit bump 132 is still located in the chute 901; when the deflector 130 rotates around the axis of the connection shaft 110, air flowing through the deflector 130 is guided to the air delivery hole on the corresponding sleeve 900, and as the two ends of the deflector 130 are respectively connected with the slide tube 120 and the sleeve 900, the slide tube 120 and the sleeve 900 synchronously rotate around the axis of the connection shaft 110 when the deflector 130 rotates around the axis of the connection shaft 110; the gas directed to the gas delivery holes by the baffle 130 enters the stirring plate 903 after passing through the gas delivery holes and flows to the spherical shell 800 through the holes in the stirring plate 903. Is dried by the dehumidified ball inside the bulb 800; at the same time, as the sleeve 900 is continuously rotated, the moist air can be sufficiently contacted with the dehumidifying balls inside the spherical shell 800. And the stirring plate 903 rotates synchronously with the sleeve 900, so as to stir the dehumidifying balls in the ball housing 800, and make the air contact with the dehumidifying balls more uniformly, thereby fully utilizing the dehumidifying balls.

After the dehumidifying balls in the innermost spherical shell 800 become wet, the resistance to rotation of the stirring plate 903 becomes large, the rotation speed becomes slow, the force of the baffle 130 rotating around the axis of the connecting shaft 110 is reduced, and the force of the baffle 130 moving outwards is increased; the baffle 130 gradually moves outwards, when the dehumidifying balls in the innermost spherical shell 800 can not dehumidify any more, the viscosity of the dehumidifying balls reaches the maximum, the resistance to rotation of the stirring plate 903 is the maximum, and the stirring plate can not rotate around the axis of the connecting shaft 110 any more, and at this time, the force of air on the baffle 130 is all used for moving the baffle 130 outwards; when the guide plate 130 moves, the slide tube 120 is driven to synchronously move through the connecting column 131, the limiting protruding block 132 continues to move towards the direction of the groove 902 in the chute 901, when the limiting protruding block 132 slides into the groove 902, the trend of the pressure spring to restore to the original state is not hindered, elastic potential energy is released, under the action of the pressure spring, the guide plate 130 moves towards the direction far away from the axis of the slide tube 120, and due to the fact that the connecting column 131 is in threaded fit with the slide tube 120, when the guide plate 130 moves away from the axis of the slide tube 120, the protruding column slides in the spiral groove 1311, the guide plate 130 rotates to be parallel with the axis of the slide tube 120, the guide assembly is in a retracted state, and air is guided to move along the axial direction of the sleeve 900 to act on the next guide mechanism from inside to outside. The moist air flowing through the innermost diversion mechanism is not influenced any more, and flows directly to the next diversion mechanism, so that the power of the air flowing is reasonably distributed on the corresponding diversion mechanism, and the phenomenon that the wetted dehumidification balls influence the air again is avoided.

In this embodiment, as shown in fig. 3 and 7, a plurality of dehumidifying chambers are uniformly distributed along the circumferential direction of the air suction pipe 701, so that more moist air can be dehumidified at the same time, and the dehumidifying efficiency is improved.

In this embodiment, as shown in fig. 5 and fig. 7-11, a gas transmission ring 904 is fixedly connected to each sleeve 900, gas transmission holes are formed in the gas transmission ring 904, and inner sleeves 804 are respectively connected to the inner and outer ends of each spherical shell 800; the inner sleeve 804 is coaxially sleeved outside the sleeve 900 and can rotate relative to the sleeve 900; each gas delivery ring 904 is mounted between the two inner sleeves 804 of one spherical shell 800; and the inner and outer ends of the gas delivery ring 904 are respectively attached to the two inner sleeves 804.

An annular friction plate 802 is arranged between each spherical shell 800 and the dehumidifying chamber, and the annular friction plate 802 is fixedly connected with the corresponding spherical shell 800; a plurality of drying stations 703 are arranged in each dehumidifying chamber at intervals, and the number of the drying stations 703 is consistent with that of the spherical shells 800; a dehumidifying station 702 is arranged between two adjacent drying stations 703, and the side of the innermost drying station 703 facing the air suction pipe 701 is the dehumidifying station 702; the inner wall of the dehumidifying station 702 is cuboid, and the inner wall of the dehumidifying station 702 is in friction contact with the annular friction plate 802, so that the spherical shell 800 can only move horizontally, the inner wall of the drying station 703 is cylindrical, and the diameter of the inner wall of the drying station 703 is larger than that of the annular friction plate 802, so that the spherical shell 800 can rotate around the axis of the sliding tube 120 when the spherical shell 800 is positioned in the drying station 703; the connecting shaft 110 is fixedly provided with a plurality of protrusions 111, and the protrusions 111 are positioned in the drying station 703.

Through setting up the dehumidification station 702 of cuboid form, but not diameter less columniform drying station 703 for the gas after the drying can directly flow out from the space between dehumidification station 702 and spherical shell 800, avoids the gas to pass through repeatedly, appears the great condition of air current resistance.

When all the dehumidifying balls cannot dehumidify the air, the rotating motor is started to drive the air suction pipe 701 to rotate, and the slide pipe 120 and the spherical shell 800 synchronously move away from the air suction pipe 701 under the action of centrifugal force. In the process, the slide tube 120 is abutted with the protrusion 111, and the annular friction plate 802 reaches the drying station 703; the drying assembly comprises a plurality of unidirectional pipes 706, and the unidirectional pipes 706 are arranged in the dehumidifying chamber and correspond to the drying stations 703 one by one; a heating assembly is disposed within each one-way tube 706; reset components are arranged in each dehumidification chamber; the air exhaust assembly is communicated with the plurality of dehumidifying chambers and the atmosphere.

When the air suction pipe 701 rotates, the one-way pipe 706 is opened, air in the upper mounting cavity is changed into hot air through the air of the heating component, and then enters the dehumidifying station 702 through the one-way pipe 706 to dehumidify and dry the dehumidifying balls in the spherical shell 800; further, the outer wall of one side of the spherical shell 800 far away from the air suction pipe 701 is provided with a plurality of guide plates 803, when the slide pipe 120 is abutted against the protrusion 111, the guide plates 803 are all in the drying station 703, when hot air enters the dehumidifying station 702 through the unidirectional pipe 706, part of the air drives the spherical shell 800 to rotate around the axis of the connecting shaft 110, the hot air can be fully contacted with the dehumidifying ball, and moisture in the dehumidifying ball can be gathered outside the spherical shell 800 under the centrifugal action, so that the dehumidifying ball in the spherical shell 800 can be quickly and fully dried.

In this embodiment, as shown in fig. 5 and 8, the reset assembly includes a first spring 801 and a plurality of second springs 122; the first spring 801 is sleeved outside the sleeve 900; one end of the first spring 801 is connected to the innermost spherical shell 800, and the other end is connected to the dehumidifying chamber; the second springs 122 are sleeved outside the connecting shaft 110 and are in one-to-one correspondence with the sliding tubes 120, one ends of the second springs are connected with the sliding tubes 120, and the other ends of the second springs are connected with the adjacent protrusions 111 of the sliding tubes 120.

As the slide 120 and the ball housing 800 move outward, the first spring 801 and the second spring 122 store energy; when all the dehumidifying balls in the ball shells 800 are dried, the rotating motor is turned off, and the air suction pipe 701 is not driven to rotate any more; centrifugal force of the spherical shell 800 and the sliding tube 120 gradually disappears, and the spherical shell 800 and the sliding tube 120 are driven to restore to the initial positions under the action of the first spring 801 and the second spring 122.

In the present embodiment, as shown in fig. 7, the exhaust assembly includes a solenoid valve 401 and a main exhaust pipe 400; a dehumidifying exhaust pipe 705 is connected above the drying station 703, the dehumidifying exhaust pipe 705 is communicated with the main exhaust pipe 400, and an upper mounting cavity extends above the main exhaust pipe 400 and is connected with the atmosphere; the solenoid valve 401 is mounted on the main exhaust pipe 400. All the dehumidifying balls in the ball shells 800 are in a wet state, and when the dehumidifying and drying cannot be continuously performed on the air, the suction pump is turned off, so that the suction air is not sucked into the suction pipe 701 any more; starting the electromagnetic valve 401 and the rotating motor, changing the air in the upper mounting cavity into hot air through the air of the heating component, and then entering the dehumidifying station 702 through the unidirectional pipe 706 to dehumidify and dry the dehumidifying balls in the spherical shell 800; and then sequentially discharged to the atmosphere through the dehumidifying exhaust pipe 705 and the main exhaust pipe 400.

In this embodiment, as shown in fig. 2, 3, 5, and 7, the air return assembly 600 includes a cover plate 500, an air return chamber, an air return pipe 601, and a connection pipe 704; the return air chamber is fixedly arranged on the partition 301; the cover plate 500 is rotatably installed in the air return chamber, and the air return chamber and the cover plate 500 define an air return chamber; the connecting pipe 704 is arranged at the outer end of the dehumidifying chamber and is communicated with the dehumidifying chamber and the air return chamber; the return air pipe 601 communicates the return air chamber with the lower mounting chamber. The air dried by the dehumidifying ball inside the bulb 800 passes through the through holes in the wall of the bulb 800 to reach the dehumidifying chamber, then flows out of the connection pipe 704 into the return air chamber, and then returns to the lower installation chamber through the return air pipe 601.

In this embodiment, as shown in fig. 2, 3 and 7, a plurality of air return pipes 601 are provided, the plurality of air return pipes 601 are uniformly distributed on the periphery of the air suction pipe 701 along the circumferential direction of the air suction pipe 701, and the dry air reaching the air return chamber is distributed and sent to different positions of the lower mounting chamber through the plurality of air return pipes 601; to complete the dehumidification of the humid air in the lower mounting chamber.

In this embodiment, as shown in fig. 1, the solar panel 200 is further included, and the solar panel 200 is disposed above the electric control cabinet 300 to store electric energy.

In combination with the above embodiment, the use principle and working process of the present invention are as follows: when the humidity sensor detects that the humidity in the lower mounting cavity reaches a preset value, the suction pump is started, so that the humid air in the lower mounting cavity enters the suction pipe 701 and then is led to the plurality of sleeves 900 respectively.

When the flowing air flows through the innermost group of guide plates 130, most of the force of the air acting on the guide plates 130 causes the guide plates 130 to rotate around the axis of the connecting shaft 110, and the other small force causes the guide plates 130 to move outwards by a preset distance, but the length of the chute 901 is greater than that of the groove 902, so that the limit bump 132 is still positioned in the chute 901; when the guide plate 130 rotates around the axis of the connecting shaft 110, gas is guided to the gas transmission ring 904 by the guide plate 130, enters the stirring plate 903 through the gas transmission hole, flows into the spherical shell 800 through the hole on the stirring plate 903, and is dried by the dehumidifying ball inside the spherical shell 800;

the dried gas passes through holes on the wall of the spherical shell 800 to reach the dehumidifying chamber, and the dried gas can directly flow to the connecting pipe 704 from a gap between the spherical shell 800 and the dehumidifying station 702, so that the situation that the gas repeatedly passes through the condition of high air flow resistance is avoided, and then is sent to different positions of the lower mounting cavity in a dispersed manner through the plurality of air return pipes 601; to complete the dehumidification of the moist air in the lower mounting cavity; the guide plate 130 rotates around the axis of the sliding tube 120 and drives the corresponding sleeve 900 to synchronously rotate through the limiting lug 132; when the sleeve 900 rotates, the stirring plate 903 stirs the dehumidifying balls in the spherical shell 800, so that the dehumidifying balls in the spherical shell 800 are in uniform contact with humid air, and the dehumidifying balls are fully utilized.

In the process that the dehumidifying balls in the innermost spherical shell 800 are changed from the dry state to the wet state, the viscosity of the dehumidifying balls is gradually increased, the resistance to rotation of the stirring plate 903 is gradually increased, the corresponding rotation speed of the sleeve 900 is slowed down, the force for driving the deflector 130 to rotate around the axis of the sleeve 900 is gradually reduced, and the force for driving the deflector 130 to move outwards is increased; the limit bump 132 moves in the chute 901 toward the recess 902, since the chute 901 is provided long enough and under the action of the second spring 122, it is ensured that the limit bump 132 does not reach into the recess 902 during the dehumidification process.

When all the dehumidifying balls in the innermost spherical shell 800 are in a wet state, the dehumidifying and drying operation cannot be performed on the gas, and at this time, the resistance to the stirring plate 903 is the greatest, and the sleeve 900 and the deflector 130 do not rotate around the axis of the sleeve 900 any more; at this time, the wind force acting on the deflector 130 cannot cause the deflector 130 to rotate, so all the wind force is used for moving the deflector 130 in a direction away from the axis of the air suction pipe 701, the movement of the deflector 130 drives the slide tube 120 to synchronously move through the connecting column 131, and at the same time, the limit bump 132 continues to move in the chute 901 towards the direction of the groove 902, and the second spring 122 stores the force; when the limit bump 132 slides into the groove 902, the trend of the compression spring to recover to be long is not hindered, and elastic potential energy is released; under the action of the compression spring, the guide plate 130 moves far away from the axis direction of the slide tube 120, and due to the fact that the connecting post 131 is in threaded fit with the slide tube 120, when the guide plate 130 moves far away from the axis direction of the slide tube 120, the convex post slides in the spiral groove 1311, the guide plate 130 rotates to be parallel to the axis of the slide tube 120, the guide assembly is in a retracted state, air is guided to move axially along the sleeve 900, and the guide assembly acts on the next guide mechanism from inside to outside.

The moist air flowing through the first group of guide plates 130 is not influenced any more, and flows directly to the next group of guide plates 130, so that the utilization rate of the dehumidifying balls is greatly increased, and the power of the air flowing is reasonably distributed on the corresponding guide plates 130, so that the sleeve 900 is ensured to have proper rotation power, the stirring effect of the stirring plate 903 is ensured, and the phenomenon that the wetted dehumidifying balls influence the air again can be avoided.

Repeating the above operation until all the dehumidifying balls in the spherical shell 800 are in a wet state, and cannot continuously dehumidify and dry the air, and at the moment, closing the suction pump, and not sucking air into the suction pipe 701; the electromagnetic valve 401 and the rotating motor are started, the rotating motor drives the air suction pipe 701 to rotate, when the air suction pipe 701 rotates, the unidirectional pipe 706 is opened, air in the upper mounting cavity enters the dehumidifying chamber through the unidirectional pipe 706, and the air passing through the heating assembly is changed into hot air; when the air suction pipe 701 rotates, the spherical shell 800 and the sleeve 900 synchronously move outwards under the action of centrifugal force; the annular friction plate 802 moves synchronously with the spherical shell 800, when the annular friction plate 802 moves to the drying station 703, the drying station 703 does not limit the rotation of the annular friction plate 802, and part of air heated by the heating component acts on the guide plate 803 to drive the spherical shell 800 to rotate; and the dehumidifying balls in the spherical shell 800 are dried, and since the spherical shell 800 is continuously rotated, moisture of the dehumidifying balls is gathered outside the spherical shell 800 under the centrifugal effect, so that the dehumidifying balls in the spherical shell 800 can be sufficiently dried. After the desiccant beads are dried by the air, the air passes through the desiccant exhaust pipe 705 and the main exhaust pipe 400 in this order, and is discharged from the exhaust port to the atmosphere.

During the synchronous outward movement of the spherical shell 800, the sleeve 900 and the slide 120, the first spring 801 and the second spring 122 store the force, the slide 120 is firstly contacted with the protrusion 111, and the slide 120 and the deflector 130 stop moving; the spherical shell 800 continues to be far away from the air suction pipe 701 under the action of centrifugal force, and the sleeve 900 synchronously moves outwards along with the spherical shell 800 while the spherical shell 800 moves, and because the outer end of the sliding pipe 120 is abutted with the bulge 111 at this time and cannot continue to move outwards, the air conveying ring 904 moves outwards relative to the sliding pipe 120, namely the air conveying ring 904 moves outwards relative to the guide plate 130; so the limit bump 132 is separated from the groove 902, and moves into the groove 901 after passing through the connection position of the smooth groove 901 and the groove 902; because the distance between the sliding groove 901 and the axis of the sliding tube 120 is smaller than the distance between the groove 902 and the axis of the sliding tube 120, the baffle 130 moves toward the axis direction of the sliding tube 120 as a whole to compress the compression spring at the moment when the limit bump 132 enters the sliding groove 901; since the connecting post 131 is screw-fitted with the slide tube 120, the boss slides in the spiral groove 1311 while the baffle 130 approaches the axis of the slide tube 120; the deflector 130 rotates, and the guide assembly resumes the deployed state; when all the dehumidifying balls in the ball shells 800 are dried, the rotating motor is turned off, and the air suction pipe 701 is not driven to rotate any more; the centrifugal force of the ball housing 800 and the sleeve 900 gradually disappears, the first spring 801 and the second spring 122 release elastic potential energy, and the slide 120 and the sleeve 900 are restored to the original positions by the first spring 801 and the second spring 122.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the invention.

Claims (7)

1. The utility model provides a soil moisture content gathers monitoring devices which characterized in that includes:

a detection instrument;

an electric control cabinet;

the partition board is horizontally arranged in the electric control cabinet, the partition board divides the interior of the electric control cabinet into an upper mounting cavity and a lower mounting cavity, and the circuits are all arranged in the lower mounting cavity;

the air suction pipe is vertically arranged on the partition board and can rotate around the axis of the air suction pipe, the upper end of the air suction pipe is positioned in the upper mounting cavity, and the lower end of the air suction pipe penetrates through the partition board and extends to the lower mounting cavity; designating an axis near the air suction pipe as an inner side along the radial direction of the air suction pipe; the axis far away from the air suction pipe is the outer side; the air suction pipe is connected with an air suction component so that when the humidity degree in the lower mounting cavity reaches a preset value, air in the lower mounting cavity enters the air suction pipe;

the dehumidifying chamber is horizontally arranged in the upper mounting cavity, extends along the radial direction of the air suction pipe, is fixedly connected with the air suction pipe and is hollow inside the dehumidifying chamber; the dehumidifying chamber is connected with an air return assembly which is communicated with the dehumidifying chamber and the lower mounting cavity; a drying component for drying the dehumidifying balls is arranged on the dehumidifying chamber;

the N dehumidification mechanisms are distributed along the axial direction of the dehumidification chamber; the dehumidifying mechanism comprises a spherical shell and a sleeve; the sleeve is coaxially arranged in the dehumidifying chamber, and can rotate relative to the dehumidifying chamber; one end of the innermost sleeve, which faces the axis of the air suction pipe, is communicated with the air suction pipe; one end of the outermost sleeve, which is far away from the axis of the air suction pipe, is closed; the side wall of the sleeve is provided with a plurality of gas transmission holes; the ball shell is sleeved on the sleeve and positioned outside the gas transmission hole; the ball shell is internally provided with a containing cavity which can contain the dehumidifying ball; the side wall of the spherical shell is provided with a plurality of through holes;

the N diversion mechanisms are respectively and correspondingly arranged in the N sleeves and are opposite to the gas transmission holes on the sleeves; the air guide mechanism is in a retracted state and an extended state, and when the air guide mechanism is in the extended state, air in the sleeve can be guided to the air transmission hole on the corresponding sleeve and the corresponding sleeve is driven to rotate; when the flow guiding mechanism is in a retracted state, guiding air to axially move along the sleeve; a connecting shaft is arranged in the dehumidifying chamber, is fixedly connected to the air suction pipe and radially extends along the air suction pipe; the guide mechanism comprises a slide tube and a plurality of guide plates, and the slide tube can axially move and is rotatably sleeved on the connecting shaft and is opposite to the gas transmission hole; the guide plates are positioned between the slide tube and the sleeve and are uniformly distributed along the circumference of the slide tube; the two ends of the guide plate are respectively connected with the slide tube and the sleeve, one end of the guide plate is rotatably arranged on the sleeve, and the other end of the guide plate is connected with the slide tube; a plurality of stirring plates with hollow structures are fixedly connected to the peripheral wall of the sleeve, each stirring plate corresponds to one gas transmission hole, and a plurality of through holes are formed in each stirring plate;

the N groups of adjusting mechanisms respectively correspond to the N diversion mechanisms, and the adjusting mechanisms are configured to enable the diversion mechanisms in the spherical shell to be adjusted from an unfolding state to a folding state when the dehumidification balls in the spherical shell cannot dehumidify; each group of adjusting mechanisms comprises a plurality of adjusting mechanisms, and the plurality of adjusting mechanisms of each group are respectively and correspondingly arranged on a plurality of guide plates arranged on one slide tube; the adjusting mechanism comprises a chute, a groove and a limiting lug; the sliding groove extends along the axial direction of the connecting shaft and is arranged on the inner wall of the sleeve; the groove is arranged at the outer side of the chute and is communicated with the chute, the distance between the groove and the axis of the slide tube is larger than the distance between the chute and the axis of the slide tube, the limit lug is arranged at one end of the guide plate, which is far away from the axis of the slide tube, and the limit lug is slidably arranged in the chute and the groove; the guide plate is provided with a connecting column at one end facing the slide tube, the connecting column is inserted on the slide tube, a pressure spring is connected between the guide plate and the slide tube, and the pressure spring has a trend of enabling the connecting column to be far away from the axis of the slide tube; the connecting column is in threaded fit with the slide tube.

2. The soil moisture content collection and monitoring device according to claim 1, wherein: the dehumidifying chamber is uniformly distributed with a plurality of dehumidifying chambers along the circumferential direction of the air suction pipe.

3. The soil moisture content collection and monitoring device according to claim 2, wherein: a plurality of drying stations are arranged in each dehumidifying chamber at intervals, and the number of the drying stations is consistent with that of the spherical shells; the spherical shell and the slide tube synchronously move horizontally, and the spherical shell can rotate around the axis of the slide tube only when in the drying station; a plurality of bulges are fixedly arranged on the connecting shaft and are positioned in the drying station; the drying assembly comprises a plurality of unidirectional pipes which are arranged in the dehumidifying chamber and correspond to the drying stations one by one; a heating component is arranged in each unidirectional pipe; reset components are arranged in each dehumidification chamber; the air exhaust assembly is communicated with the plurality of dehumidifying chambers and the atmosphere.

4. The soil moisture content collection and monitoring device according to claim 3, wherein: the reset assembly comprises a first spring and a plurality of second springs; the first spring is sleeved outside the sleeve, one end of the first spring is connected with the innermost spherical shell, and the other end of the first spring is connected with the dehumidifying chamber; the second springs are sleeved outside the connecting shaft and correspond to the sliding pipes one by one, one ends of the second springs are connected to the sliding pipes, and the other ends of the second springs are connected to adjacent bulges of the sliding pipes.

5. The soil moisture content collection and monitoring device according to claim 4, wherein: the exhaust assembly comprises an electromagnetic valve and a main exhaust pipe; a dehumidifying exhaust pipe is connected above the drying station, is communicated with a main exhaust pipe, extends out of an upper mounting cavity above the main exhaust pipe and is connected with the atmosphere; the solenoid valve is installed on the main exhaust pipe.

6. The soil moisture content collection and monitoring device according to claim 1, wherein: the air return assembly comprises a cover plate, an air return chamber, an air return pipe and a connecting pipe; the air return chamber is fixedly arranged on the partition board; the cover plate is rotatably arranged in the air return chamber, and the air return chamber and the cover plate define an air return chamber; the connecting pipe is communicated with the outer end of the dehumidifying chamber and the air return cavity; the air return pipe is communicated with the air return cavity and the lower mounting cavity.

7. The soil moisture content collection and monitoring device according to claim 6, wherein: the air return pipes are arranged in a plurality and uniformly distributed on the periphery of the air suction pipe along the circumferential direction of the air suction pipe.