CN116471820A - Hydrologic water resource telemetering terminal - Google Patents

Abstract

The invention discloses a hydrologic water resource remote measuring terminal, and belongs to the technical field of hydrologic water resources. This hydrology water resource telemetering measurement terminal through setting up air pump and filter unit, when the air pump operation, the air pump then can carry the air to the standing groove in the terminal body along the blast pipe, make gas can advance the filtration of filter screen when flowing along the standing groove, realize the filtration to moisture and impurity in the gas, then gas then can get into the air groove of taking a breath shell top, because the heat dissipation pipe route is longer, and the heat is lower, lead to steam can condense fast in the heat dissipation pipe is inside, make this terminal can effectually stop the condition that contains the moisture in the external gas when realizing inside gaseous interaction thereby dispel the heat, thereby effectually avoided steam to lead to the fact the condition emergence of corruption to this terminal internal element, the life of this terminal has been improved, avoid damaging this increase maintenance cost because of this terminal, and the actual result of use of this terminal has been ensured.

Description

Hydrologic water resource telemetering terminal

Technical Field

The invention relates to the technical field of hydrologic water resources, in particular to a hydrologic water resource telemetry terminal.

Background

The hydrologic water resource telemetering terminal is a novel remote control terminal device specially developed for hydrologic telemetering, hydrologic condition monitoring, reservoir automation monitoring and water resource monitoring, can automatically collect, store and display water resource hydrologic related data such as water level, rainfall, flow, battery voltage and temperature, and is in remote communication with a monitoring center through channels such as serial ports, GSM short messages and GPRS networks. The hydrologic water resource telemetering terminal is provided with various interface resources, including analog signal acquisition, switching value input, output, pulse signal input, temperature monitoring, voltage monitoring and the like, can be connected with a tipping bucket rain gauge, a snow gauge, a radar water level gauge, a bubble water level gauge and an electronic water gauge to form a rain gauge station and a water level station, and can be connected with a wind speed and wind direction, a temperature, a ground temperature and an atmospheric pressure sensor to form a telemetering weather station and a portable weather station, so that the hydrologic water resource telemetering terminal is multifunctional equipment.

When the existing hydrologic water resource telemetry terminal is used, the hydrologic water resource telemetry terminal is generally placed on the bank of a river for better monitoring the water conditions, and the water vapor density on the bank of the river is too high, so that external water vapor easily enters the terminal in a state that a heat exchange structure in the terminal continuously operates, corrosion is easily caused to electric elements in the terminal, the service life of the hydrologic water resource telemetry terminal is shortened, the cost of staff for maintaining the hydrologic water resource telemetry terminal is increased, the water vapor is difficult to recycle, the practical use effect of the hydrologic water resource telemetry terminal is limited, and meanwhile, the normal monitoring of the hydrologic water condition by the hydrologic water resource telemetry terminal is also easily influenced.

Disclosure of Invention

This section is intended to outline some aspects of embodiments of the invention and to briefly introduce some preferred embodiments. Some simplifications or omissions may be made in this section as well as in the description summary and in the title of the application, to avoid obscuring the purpose of this section, the description summary and the title of the invention, which should not be used to limit the scope of the invention.

The present invention has been made in view of the above and/or existing problems with hydrologic water resources.

Therefore, the technical problem to be solved by the invention is that when the hydrologic water resource telemetry terminal is used, the hydrologic water resource telemetry terminal is generally placed on the bank of a river in order to better monitor the water conditions, and the water vapor density of the bank of the river is overlarge, so that external water vapor easily enters the terminal in the state that a heat exchange structure in the terminal continuously operates, thereby easily corroding electric elements in the terminal, shortening the service life of the hydrologic water resource telemetry terminal, increasing the cost of staff for maintaining the hydrologic water resource telemetry terminal, and being difficult to recycle the water vapor, thereby limiting the practical use effect of the hydrologic water resource telemetry terminal and easily influencing the normal monitoring of the hydrologic water conditions of the hydrologic water resource telemetry terminal.

In order to achieve the above purpose, the present invention provides the following technical solutions: a hydrologic water resource telemetering terminal comprises,

the terminal machine mechanism comprises a terminal machine body, a placing groove, a ventilation assembly arranged in the placing groove, a plurality of heat exchange assemblies communicated with the ventilation assembly, a sealing assembly and mounting assemblies, wherein the number of the mounting assemblies is two, and the two mounting assemblies are respectively arranged on two sides of the terminal machine body; the method comprises the steps of,

the dehumidifying mechanism comprises a dehumidifying component, a filtering component, a transmission component connected with the dehumidifying component, a connecting shaft and a gas-liquid separation component, wherein the connecting shaft is arranged in the transmission component, the number of the gas-liquid separation components is a plurality of, and the plurality of the gas-liquid separation components are all arranged in a placing groove.

As a further aspect of the invention: the terminal is characterized in that a placing groove is formed in the terminal body, two sides of the inner wall of the placing groove are fixedly connected with the left side and the right side of the ventilation assembly respectively, the back of the ventilation assembly is fixedly connected with four heat exchange assemblies, the four heat exchange assemblies are communicated with the ventilation assembly, and a sealing assembly is clamped outside the heat exchange assemblies.

As a further aspect of the invention: the lower part of the inner wall of the placing groove is provided with an element mounting groove, the left side and the right side of the terminal body are provided with two limiting sliding grooves, the two limiting sliding grooves on one side are slidably connected with the same mounting assembly, the mounting assembly is communicated with an air outlet on the front side of the terminal body, and one side of the terminal body is provided with a butt joint groove;

the filter assembly is positioned in the butt joint groove.

As a further aspect of the invention: the ventilation assembly comprises a ventilation shell, and an air groove is formed in the upper part of the ventilation shell;

the air exchanging shell is communicated with the placing groove through the air groove, the left side and the right side of the air exchanging shell are fixedly connected with the left side and the right side of the inner wall of the placing groove respectively, and the air exchanging shell is communicated with the four heat exchanging components.

As a further aspect of the invention: the heat exchange assembly comprises a ventilation catheter, the other end of the ventilation catheter is communicated with a heat dissipation catheter, and a plurality of cooling fins are fixedly connected to the outside of the heat dissipation catheter;

one end of the ventilation catheter is communicated with the ventilation shell, the sealing assembly is fixedly connected outside the heat dissipation catheter, and the other end of the heat dissipation catheter passes through the sealing assembly to be communicated with the gas-liquid separation assembly;

the sealing assembly comprises a sealing cover, and a plurality of exhaust ports are formed above the sealing cover;

the sealing cover is fixedly connected to the back of the terminal body.

As a further aspect of the invention: the mounting assembly comprises two limit sliding blocks, the two limit sliding blocks are fixedly connected with the same first clamping plate, a pressure sleeve is fixedly connected above the first clamping plate, the first clamping plate is fixedly connected with the second clamping plate through the pressure sleeve, a pressure valve is arranged outside the pressure sleeve, the top end of the pressure sleeve is communicated with an exhaust pipe arranged above the second clamping plate, and the other end of the exhaust pipe is communicated with a connecting cover;

the limiting slide block is slidably connected in the limiting groove, the second clamping plate is fixedly connected to one side of the terminal body, and the connecting cover is fixedly connected in the exhaust groove arranged on the front face of the terminal body.

As a further aspect of the invention: the dehumidifying component is in transmission connection with the connecting shaft through the transmission component, one end of the connecting shaft is sleeved with a bearing, two groups of cleaning scrapers are fixedly connected outside the connecting shaft, and the cleaning scrapers are clamped in the filtering component;

the dehumidification subassembly fixed connection is on the terminal body, the bearing joint is in one side of standing groove inner wall, filtering component sliding connection is in the butt joint inslot, gas-liquid separation subassembly fixed connection is in the below of standing groove inner wall, gas-liquid separation subassembly is linked together with component mounting groove, sealing component and air exchange pipe respectively.

As a further aspect of the invention: the dehumidifying component comprises an air pump, a conduit is arranged at one side port of the air pump, and an air inlet cover is arranged at the other side port of the air pump;

the air pump discharges air into the placing groove through the guide pipe, the air pump extracts air through the air inlet cover, the air pump is fixedly connected to the terminal body, and the air pump is in transmission connection with the transmission assembly through the driving shaft;

the transmission assembly comprises a first transmission wheel, a transmission belt is sleeved outside the first transmission wheel, and the first transmission wheel is in transmission connection with a second transmission wheel through the transmission belt;

the first driving wheel is in driving connection with a driving shaft of the air pump, and the second driving wheel is in driving connection with the connecting shaft.

As a further aspect of the invention: the filtering assembly comprises a sealing block, a plurality of positioning magnetic blocks are fixedly connected to the outside of the sealing block, a handle is fixedly connected to one side of the sealing block, a filter screen is fixedly connected to the other side of the sealing block, and the filter screen is arc-shaped;

the sealing block is clamped in the butt joint groove, the positioning magnetic block is adsorbed in the butt joint groove, and the cleaning scraping plate is in lap joint with the inner wall of the filter screen.

As a further aspect of the invention: the gas-liquid separation assembly comprises a separation cover, the separation cover is U-shaped, a gas outlet is formed in the outside of the separation cover, a guide cover is fixedly connected to the outside of the separation cover, circulation grooves are formed in the lower portions of the guide cover and the separation cover, a connection port is formed in one side of the guide cover, the guide cover is communicated with the separation cover through the gas outlet and the connection port, a separation plate is arranged in the separation cover, the separation plate is arc-shaped, the separation plate is fixedly connected in the circulation grooves, and the separation plate is located below the gas outlet;

the separation cover and the guide cover are fixedly connected below the inner wall of the placing groove, the other end of the guide cover is communicated with the element installation groove, the air inlet of the guide cover is communicated with the outlet of the heat dissipation conduit, and the air outlet of the guide cover is communicated with the sealing cover.

Compared with the prior art, the invention has the beneficial effects that:

this hydrology water resource telemetering measurement terminal through setting up air pump, heat dissipation pipe and filter unit, when the air pump operation, the air pump then can extract external gas, and carry the internal standing groove of terminal to with gas along the blast pipe, because the inside filter unit that is provided with of standing groove, make gas can advance the filtration of filter screen when flowing along the standing groove, realize the first filtration treatment to moisture and impurity in the extraction gas, then gas then can get into the air tank of taking a breath shell top, and in four air exchange pipes and heat dissipation pipe fast along the air tank, when gas moves along the heat dissipation pipe, because the heat dissipation pipe route is longer, and the heat is lower, lead to steam can condense fast in heat dissipation pipe inside, make this terminal can effectually stop the condition that contains moisture in the external gas when realizing inside gaseous interaction and radiating, thereby effectually avoided steam to the condition emergence that causes the corruption to this terminal internal element, the life of this terminal has been improved, avoid this terminal damage this increase maintenance cost, and ensured the actual use effect of this terminal.

This hydrological water resource telemetering measurement terminal, through setting up the separation cover, division board and kuppe, after the heat dissipation pipe condenses the steam, then can carry gas and one kind of after the steam after condensing to the separation cover in, when gas and after the steam after the condensation get into the separation cover, because the steam weight after the condensation is higher, make the steam after the condensation can be located the below of separation cover inside, and gas then can be located the top of separation cover inside, after the steam after the continuous promotion of rear gas and condensation, make the inside gas of entering the separation cover and the steam after the condensation can move forward fast, the gas of the top then can pass gas outlet and connector and get into the component mounting groove along the division board at this moment, and the steam after the below condenses can then be discharged to the seal cover in again along the separation cover, make this terminal body can be after collecting the steam and gas separation, avoid the steam to get into the terminal body in, and can carry out secondary recycle, and then improved the environmental protection effect of this terminal, the resource waste is avoided appearing.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed in the description of the embodiments will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art. Wherein:

fig. 1 is a schematic perspective view 1 of a hydrological water resource telemetry terminal according to an embodiment of the present invention.

Fig. 2 is a schematic perspective view 2 of a hydrological water resource telemetry terminal according to an embodiment of the present invention.

Fig. 3 is a schematic diagram of a three-dimensional cross-sectional structure of a terminal body in a hydrological water resource telemetry terminal according to an embodiment of the present invention.

Fig. 4 is a schematic structural diagram of a ventilation assembly in a hydrological water resource telemetry terminal according to an embodiment of the present invention.

Fig. 5 is a schematic structural diagram of a dehumidifying component in a hydrological water resource telemetry terminal according to an embodiment of the present invention.

Fig. 6 is a schematic diagram of a gas-liquid separation assembly in a hydrological water resource telemetry terminal according to an embodiment of the present invention.

Fig. 7 is a schematic diagram of an explosion structure of a gas-liquid separation component in a hydrological water resource telemetry terminal according to an embodiment of the present invention.

Fig. 8 is a schematic structural diagram of a docking slot in a hydrological water resource telemetry terminal according to an embodiment of the present invention.

Fig. 9 is a schematic structural diagram of a filtering component in a hydrological water resource telemetry terminal according to an embodiment of the invention.

Fig. 10 is an enlarged schematic diagram of a hydrological water resource telemetry terminal according to an embodiment of the present invention at a position a in fig. 9.

Fig. 11 is a schematic diagram of an explosion structure of a connection shaft in a hydrological water resource telemetry terminal according to an embodiment of the present invention.

Detailed Description

In order that the above-recited objects, features and advantages of the present invention will become more readily apparent, a more particular description of the invention will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, but the present invention may be practiced in other ways other than those described herein, and persons skilled in the art will readily appreciate that the present invention is not limited to the specific embodiments disclosed below.

In the following detailed description of the embodiments of the present invention, the cross-sectional view of the device structure is not partially enlarged to a general scale for the convenience of description, and the schematic is merely an example, which should not limit the scope of the present invention. In addition, the three-dimensional dimensions of length, width and depth should be included in actual fabrication.

Further still, reference herein to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic may be included in at least one implementation of the invention. The appearances of the phrase "in one embodiment" in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments.

Example 1

As shown in fig. 1-3 and fig. 6, the present invention provides a technical solution: a hydrologic water resource telemetering terminal comprises,

the terminal mechanism 100 comprises a terminal body 101, a placing groove 102, a ventilation assembly 103 arranged in the placing groove 102, a plurality of heat exchange assemblies 104 communicated with the ventilation assembly 103, a sealing assembly 105 and mounting assemblies 108, wherein the number of the mounting assemblies 108 is two, and the two mounting assemblies 108 are respectively arranged on two sides of the terminal body 101; the method comprises the steps of,

the dehumidifying mechanism 200 comprises a dehumidifying component 201, a filtering component 202, a transmission component 203 connected with the dehumidifying component 201, a connecting shaft 204 and a gas-liquid separation component 207, wherein the connecting shaft 204 is arranged in the transmission component 203, the number of the gas-liquid separation components 207 is a plurality of, and the plurality of the gas-liquid separation components 207 are all arranged in the placing groove 102.

Further: a placing groove 102 is formed in the terminal body 101, two sides of the inner wall of the placing groove 102 are fixedly connected with the left side and the right side of the ventilation assembly 103 respectively, the back surface of the ventilation assembly 103 is fixedly connected with four heat exchange assemblies 104, the four heat exchange assemblies 104 are communicated with the ventilation assembly 103, and a sealing assembly 105 is clamped outside the heat exchange assemblies 104;

because the connecting shaft 204 and the cleaning scraping plate 206 are arranged, when the air pump 201a operates, the air pump 201a synchronously drives the second driving wheel 203c and the connecting shaft 204 to rotate at high speed in a manner of driving the first driving wheel 203a to rotate, and at the moment, the connecting shaft 204 simultaneously drives the cleaning scraping plate 206 to rotate in the filter screen 202d, so that impurities accumulated during gas filtering in the filter screen 202d are cleaned, and the effect of filtering the gas by the filter screen 202d is prevented from being influenced due to long-time use.

The below of standing groove 102 inner wall has seted up component mounting groove 106, and two spacing spouts 107 have all been seted up to the left and right sides of terminal body 101, and two spacing spouts 107 that lie in one side slide connection has same installation component 108, and installation component 108 is linked together with terminal body 101 positive gas outlet, and butt joint groove 109 has been seted up to one side of terminal body 101, and filter component 202 lies in butt joint groove 109.

In this embodiment, through setting up air pump 201a, heat dissipation pipe 104b and filter module 202, when air pump 201a operates for this terminal machine can effectually stop the condition that contains moisture in the external gas when realizing inside gaseous interaction thereby the heat dissipation, thereby effectually avoided steam to the condition emergence that causes the corruption to this terminal machine internal element, improved the life of this terminal machine, avoided this increase maintenance's cost because of this terminal machine damages, and ensured the actual result of use of this terminal machine.

Example 2

In conjunction with fig. 2-5 and fig. 10, we find: the ventilation assembly 103 comprises a ventilation shell 103a, an air groove 103b is formed in the upper portion of the ventilation shell 103a, the ventilation shell 103a is communicated with the placing groove 102 through the air groove 103b, the left side and the right side of the ventilation shell 103a are fixedly connected with the left side and the right side of the inner wall of the placing groove 102 respectively, the ventilation shell 103a is communicated with four heat exchange assemblies 104, each heat exchange assembly 104 comprises a ventilation duct 104a, the other end of each ventilation duct 104a is communicated with a heat dissipation duct 104b, a plurality of cooling fins 104c are fixedly connected to the outer portion of each heat dissipation duct 104b, one end of each ventilation duct 104a is communicated with the ventilation shell 103a, a sealing assembly 105 is fixedly connected to the outer portion of each heat dissipation duct 104b, the other end of each heat dissipation duct 104b is communicated with the gas-liquid separation assembly 207 through a sealing assembly 105, the sealing assembly 105 comprises a sealing cover 105a, a plurality of air vents 105b are formed in the upper portion of the sealing cover 105a, and the sealing cover 105a is fixedly connected to the back surface of the terminal body 101.

The installation assembly 108 comprises two limit sliding blocks 108a, the two limit sliding blocks 108a are fixedly connected with the same first clamping plate 108b, a pressure sleeve 108d is fixedly connected above the first clamping plate 108b, the first clamping plate 108b is fixedly connected with a second clamping plate 108c through the pressure sleeve 108d, a pressure valve is arranged outside the pressure sleeve 108d, the top end of the pressure sleeve 108d is communicated with an exhaust pipe 108e arranged above the second clamping plate 108c, the other end of the exhaust pipe 108e is communicated with a connecting cover 108f, the limit sliding blocks 108a are slidably connected in a limit groove, the second clamping plate 108c is fixedly connected to one side of the terminal body 101, the connecting cover 108f is fixedly connected in an exhaust groove 103b arranged on the front surface of the terminal body 101, when the filter screen 202d needs to be cleaned integrally, the filter screen 202a connected with the seal block 202a can be cleaned only through a grip 202c, after the filter screen 202a and the filter screen 202d are installed in the butt joint groove 109 again through a magnetic block, the filter screen 202a can be cleaned quickly, and the difficulty of installing and removing the filter screen 202d can be greatly reduced by adopting a nut installing method or a method of removing the filter screen 202 d;

the dehumidifying component 201 is in transmission connection with the connecting shaft 204 through the transmission component 203, one end of the connecting shaft 204 is sleeved with the bearing 205, two groups of cleaning scrapers 206 are fixedly connected to the outside of the connecting shaft 204, the cleaning scrapers 206 are clamped in the filtering component 202, the dehumidifying component 201 is fixedly connected to the terminal body 101, the bearing 205 is clamped on one side of the inner wall of the placing groove 102, the filtering component 202 is slidingly connected in the butt joint groove 109, the gas-liquid separation component 207 is fixedly connected to the lower part of the inner wall of the placing groove 102, the gas-liquid separation component 207 is respectively communicated with the element installation groove 106, the sealing component 105 and the ventilation guide pipe 104a, the dehumidifying component 201 comprises the air pump 201a, one side port of the air pump 201a is provided with the guide pipe 201b, the other side port of the air pump 201a is provided with the air inlet cover 201c, the air pump 201a discharges air into the placing groove 102 through the guide pipe 201b, the air pump 201a is fixedly connected to the terminal body 101 through the air inlet cover 201c, the air pump 201a is in transmission connection with the transmission component 203, the transmission component 203 comprises a first transmission wheel 203a, the first transmission wheel 203a is sleeved with a transmission belt 203b, the transmission wheel 203 is respectively, the transmission shaft 203b is connected with the second transmission wheel 203a transmission shaft 203a through the transmission belt 203b, and the transmission wheel 203c is connected with the transmission shaft 203 c.

In this embodiment: through setting up separation cover 207a, division board 207c and kuppe 207d for this terminal body 101 can effectually separate steam and gas after finishing collecting steam, avoids steam to get into in the terminal body 101, and can carry out secondary recycle to steam, and then has improved the environmental protection effect of this terminal, avoids appearing the condition emergence of wasting of resources.

Example 3

In connection with fig. 6-9 and fig. 11, we will be: the filter assembly 202 comprises a seal block 202a, a plurality of positioning magnetic blocks are fixedly connected to the outside of the seal block 202a, a handle 202c is fixedly connected to one side of the seal block 202a, a filter screen 202d is fixedly connected to the other side of the seal block 202a, the filter screen 202d is arc-shaped, the seal block 202a is clamped in the butt joint groove 109, the positioning magnetic blocks are adsorbed in the butt joint groove 109, and the cleaning scraping plate 206 is in lap joint with the inner wall of the filter screen 202 d;

because the cleaning scraping plate 206 is composed of a plurality of arc-shaped scraping plates, the cleaning scraping plate 206 can collect the impurities under cleaning at the same time in the process of cleaning the filter screen 202d, so that the situation that the impurities splash or are accumulated in the filter screen 202d is avoided;

the gas-liquid separation assembly 207 comprises a separation cover 207a, wherein the separation cover 207a is in a U shape, a gas outlet 207b is formed in the outside of the separation cover 207a, a guide cover 207d is fixedly connected to the outside of the separation cover 207a, a circulation groove 207f is formed in the lower parts of the guide cover 207d and the separation cover 207a, a connecting port 207e is formed in one side of the guide cover 207d, the guide cover 207d is communicated with the separation cover 207a through the gas outlet 207b and the connecting port 207e, a separation plate 207c is arranged in the separation cover 207a, the separation plate 207c is in an arc shape, the separation plate 207c is fixedly connected in the circulation groove 207f, the separation plate 207c is located below the gas outlet 207b, the separation cover 207a and the guide cover 207d are fixedly connected to the lower part of the inner wall of the placing groove 102, the other end of the guide cover 207d is communicated with the element mounting groove 106, an air inlet of the guide cover 207d is communicated with an outlet of the heat dissipation pipe 104b, and an air outlet of the guide cover 207d is communicated with the sealing cover 105 a.

In this embodiment: when the air enters the component mounting groove 106 through the separating cover 207a and the air guide cover 207d, the air flow rate inside the component mounting groove 106 is increased, so that the heat dissipation effect of the component surface is increased, meanwhile, along with the discharge of the air, a large amount of air enters the pressure sleeve 108d along the exhaust pipe 108e, so that the internal pressure of the pressure sleeve 108d is increased, and the first clamping plate 108b is pushed to slide along the sliding groove, at the moment, the first clamping plate 108b is in principle the second clamping plate 108c, so that the friction force between the external bolt, the nut and the wall body is increased, and meanwhile, when the internal pressure of the pressure sleeve 108d is accumulated to a specified value, the control valve on the surface of the pressure sleeve 108d discharges the air.

The working principle of the invention is as follows: when the terminal is used, the terminal is required to be installed, and the terminal can be put into use after the installation is finished;

when the terminal is installed, external bolts are required to pass through the installation holes above the first clamping plate 108b and the second clamping plate 108c, and then the first clamping plate 108b and the second clamping plate 108c are fastened at the appointed installation positions through the external bolts;

when the air pump 201a operates, the air pump 201a extracts external air and conveys the air into the placing groove 102 in the terminal body 101 along the guide pipe 201b, and as the filtering component 202 is arranged in the placing groove 102, the air can enter the filtering net 202d when flowing along the placing groove 102, so as to realize the primary filtering treatment of moisture and impurities in the extracted air, and then the air can enter the air groove 103b above the ventilation shell 103a and quickly enter the four ventilation guide pipes 104a and the heat dissipation guide pipes 104b along the air groove 103b, and when the air moves along the heat dissipation guide pipes 104b, the water vapor can be quickly condensed in the heat dissipation guide pipes 104b due to the longer path of the heat dissipation guide pipes 104b and lower heat;

when the heat dissipation conduit 104b condenses moisture, one of the gas and the condensed moisture is conveyed into the separation cover 207a, when the gas and the condensed moisture enter the separation cover 207a, the condensed moisture is located below the inside of the separation cover 207a due to the higher weight of the condensed moisture, and the gas is located above the inside of the separation cover 207a, when the rear gas and the condensed moisture are continuously pushed, the gas and the condensed moisture entering the inside of the separation cover 207a can rapidly move forward, and at the moment, the uppermost gas passes through the gas outlet 207b and the connection port 207e along the partition plate 207c and enters the element installation groove 106 through the guide cover 207d, and the condensed moisture below is discharged into the sealing cover 105a again along the separation cover 207 a;

when the air enters the component mounting groove 106 through the separation cover 207a and the air guide cover 207d, the air flow rate in the component mounting groove 106 is increased, so that the heat dissipation effect of the component surface is increased, meanwhile, along with the discharge of the air, a large amount of air enters the pressure sleeve 108d along the exhaust pipe 108e, so that the internal pressure of the pressure sleeve 108d is increased, and the first clamping plate 108b is pushed to slide along the sliding groove, at the moment, the first clamping plate 108b is in principle the second clamping plate 108c, so that the friction force between the external bolt, the nut and the wall body is increased, and meanwhile, when the internal pressure of the pressure sleeve 108d is accumulated to a specified value, the control valve on the surface of the pressure sleeve 108d discharges the air;

when the air pump 201a operates, the air pump 201a synchronously drives the second driving wheel 203c and the connecting shaft 204 to rotate at high speed in a manner of driving the first driving wheel 203a to rotate, and at the moment, the connecting shaft 204 simultaneously drives the cleaning scraping plate 206 to rotate in the filter screen 202d, so that impurities accumulated during gas filtration in the filter screen 202d are cleaned;

when the filter screen 202d needs to be cleaned integrally, the sealing block 202a can be taken out only by means of grasping the handle 202c, meanwhile, the filter screen 202d connected with the sealing block 202a can be cleaned, and after the cleaning is finished, the sealing block 202a and the filter screen 202d can be mounted in the butt joint groove 109 again only by means of the magnetic block.

It is important to note that the construction and arrangement of the present application as shown in a variety of different exemplary embodiments is illustrative only. Although only a few embodiments have been described in detail in this disclosure, those skilled in the art who review this disclosure will readily appreciate that many modifications are possible (e.g., variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters (e.g., temperature, pressure, etc.), mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter described in this application. For example, elements shown as integrally formed may be constructed of multiple parts or elements, the position of elements may be reversed or otherwise varied, and the nature or number of discrete elements or positions may be altered or varied. Accordingly, all such modifications are intended to be included within the scope of present invention. The order or sequence of any process or method steps may be varied or re-sequenced according to alternative embodiments. In the claims, any means-plus-function clause is intended to cover the structures described herein as performing the recited function and not only structural equivalents but also equivalent structures. Other substitutions, modifications, changes and omissions may be made in the design, operating conditions and arrangement of the exemplary embodiments without departing from the scope of the present inventions. Therefore, the invention is not limited to the specific embodiments, but extends to various modifications that nevertheless fall within the scope of the appended claims.

Furthermore, in an effort to provide a concise description of the exemplary embodiments, all features of an actual implementation may not be described (i.e., those not associated with the best mode presently contemplated for carrying out the invention, or those not associated with practicing the invention).

It should be appreciated that in the development of any such actual implementation, as in any engineering or design project, numerous implementation-specific decisions may be made. Such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure.

It should be noted that the above embodiments are only for illustrating the technical solution of the present invention and not for limiting the same, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the technical solution of the present invention may be modified or substituted without departing from the spirit and scope of the technical solution of the present invention, which is intended to be covered in the scope of the claims of the present invention.

Claims (10)

1. A hydrologic water resource telemetering terminal machine which characterized in that: comprising the steps of (a) a step of,

the terminal mechanism (100) comprises a terminal body (101), a placing groove (102), a ventilation assembly (103) arranged in the placing groove (102), a plurality of heat exchange assemblies (104) communicated with the ventilation assembly (103), a sealing assembly (105) and mounting assemblies (108), wherein the number of the mounting assemblies (108) is two, and the two mounting assemblies (108) are respectively arranged on two sides of the terminal body (101); the method comprises the steps of,

the dehumidifying mechanism (200) comprises a dehumidifying component (201), a filtering component (202), a transmission component (203) connected with the dehumidifying component (201), a connecting shaft (204) and a gas-liquid separation component (207), wherein the connecting shaft (204) is arranged in the transmission component (203), the number of the gas-liquid separation components (207) is a plurality of, and the plurality of the gas-liquid separation components (207) are all arranged in the placing groove (102).

2. The hydrological water resource telemetry terminal of claim 1, wherein: the terminal comprises a terminal body (101), wherein a placing groove (102) is formed in the terminal body (101), two sides of the inner wall of the placing groove (102) are fixedly connected with the left side and the right side of a ventilation assembly (103) respectively, four heat exchange assemblies (104) are fixedly connected to the back of the ventilation assembly (103), the four heat exchange assemblies (104) are communicated with the ventilation assembly (103), and a sealing assembly (105) is clamped outside the heat exchange assemblies (104).

3. The hydrological water resource telemetry terminal as claimed in claim 2, wherein: an element mounting groove (106) is formed below the inner wall of the placing groove (102), two limiting sliding grooves (107) are formed in the left side and the right side of the terminal body (101), the two limiting sliding grooves (107) on one side are slidably connected with the same mounting assembly (108), the mounting assembly (108) is communicated with an air outlet on the front side of the terminal body (101), and a butt joint groove (109) is formed in one side of the terminal body (101);

the filter assembly (202) is positioned within the docking slot (109).

4. A hydrological water resource telemetry terminal as claimed in claim 3, wherein: the ventilation assembly (103) comprises a ventilation shell (103 a), and an air groove (103 b) is formed above the ventilation shell (103 a);

the air exchanging shell (103 a) is communicated with the placing groove (102) through the air groove (103 b), the left side and the right side of the air exchanging shell (103 a) are fixedly connected with the left side and the right side of the inner wall of the placing groove (102) respectively, and the air exchanging shell (103 a) is communicated with the four heat exchanging components (104).

5. The hydrological water resource telemetry terminal of claim 4, wherein: the heat exchange assembly (104) comprises a ventilation catheter (104 a), the other end of the ventilation catheter (104 a) is communicated with a heat dissipation catheter (104 b), and a plurality of heat dissipation fins (104 c) are fixedly connected to the outside of the heat dissipation catheter (104 b);

one end of the ventilation duct (104 a) is communicated with the ventilation shell (103 a), the sealing component (105) is fixedly connected outside the heat dissipation duct (104 b), and the other end of the heat dissipation duct (104 b) passes through the sealing component (105) to be communicated with the gas-liquid separation component (207);

the sealing assembly (105) comprises a sealing cover (105 a), and a plurality of exhaust ports (105 b) are formed above the sealing cover (105 a);

the sealing cover (105 a) is fixedly connected to the back surface of the terminal body (101).

6. A hydrological water resource telemetry terminal as claimed in claim 3, wherein: the mounting assembly (108) comprises two limit sliding blocks (108 a), the two limit sliding blocks (108 a) are fixedly connected with the same first clamping plate (108 b), a pressure sleeve (108 d) is fixedly connected above the first clamping plate (108 b), the first clamping plate (108 b) is fixedly connected with a second clamping plate (108 c) through the pressure sleeve (108 d), a pressure valve is arranged outside the pressure sleeve (108 d), the top end of the pressure sleeve (108 d) is communicated with an exhaust pipe (108 e) arranged above the second clamping plate (108 c), and the other end of the exhaust pipe (108 e) is communicated with a connecting cover (108 f);

the limiting slide block (108 a) is slidably connected to the limiting groove, the second clamping plate (108 c) is fixedly connected to one side of the terminal body (101), and the connecting cover (108 f) is fixedly connected to the inside of the exhaust groove (103 b) arranged on the front face of the terminal body (101).

7. The hydrological water resource telemetry terminal as claimed in claim 1 or 5, wherein: the dehumidifying assembly (201) is in transmission connection with the connecting shaft (204) through the transmission assembly (203), one end of the connecting shaft (204) is sleeved with the bearing (205), two groups of cleaning scrapers (206) are fixedly connected outside the connecting shaft (204), and the cleaning scrapers (206) are clamped in the filtering assembly (202);

the dehumidification assembly (201) is fixedly connected to the terminal body (101), the bearing (205) is clamped on one side of the inner wall of the placing groove (102), the filtering assembly (202) is slidably connected to the inside of the butt joint groove (109), the gas-liquid separation assembly (207) is fixedly connected to the lower portion of the inner wall of the placing groove (102), and the gas-liquid separation assembly (207) is respectively communicated with the element installation groove (106), the sealing assembly (105) and the ventilation catheter (104 a).

8. The hydrological water resource telemetry terminal of claim 7, wherein: the dehumidifying assembly (201) comprises an air pump (201 a), a conduit (201 b) is arranged at one side port of the air pump (201 a), and an air inlet cover (201 c) is arranged at the other side port of the air pump (201 a);

the air pump (201 a) discharges air into the placing groove (102) through the guide pipe (201 b), the air pump (201 a) extracts air through the air inlet cover (201 c), the air pump (201 a) is fixedly connected to the terminal body (101), and the air pump (201 a) is in transmission connection with the transmission component (203) through the driving shaft;

the transmission assembly (203) comprises a first transmission wheel (203 a), a transmission belt (203 b) is sleeved outside the first transmission wheel (203 a), and the first transmission wheel (203 a) is in transmission connection with a second transmission wheel (203 c) through the transmission belt (203 b);

the first driving wheel (203 a) is in transmission connection with a driving shaft of the air pump (201 a), and the second driving wheel (203 c) is in transmission connection with the connecting shaft (204).

9. The hydrological water resource telemetry terminal of claim 8, wherein: the filtering assembly (202) comprises a sealing block (202 a), a plurality of positioning magnetic blocks are fixedly connected to the outside of the sealing block (202 a), a grip (202 c) is fixedly connected to one side of the sealing block (202 a), a filter screen (202 d) is fixedly connected to the other side of the sealing block (202 a), and the filter screen (202 d) is arc-shaped;

the sealing block (202 a) is clamped in the butt joint groove (109), the positioning magnetic block is adsorbed in the butt joint groove (109), and the cleaning scraping plate (206) is overlapped with the inner wall of the filter screen (202 d).

10. The hydrological water resource telemetry terminal of claim 7, wherein: the gas-liquid separation assembly (207) comprises a separation cover (207 a), the separation cover (207 a) is U-shaped, a gas outlet (207 b) is formed in the outside of the separation cover (207 a), a guide cover (207 d) is fixedly connected to the outside of the separation cover (207 a), a circulation groove (207 f) is formed in the lower portion of the guide cover (207 d) and the lower portion of the separation cover (207 a), a connecting port (207 e) is formed in one side of the guide cover (207 d), the guide cover (207 d) is communicated with the separation cover (207 a) through the gas outlet (207 b) and the connecting port (207 e), a separation plate (207 c) is arranged in the separation cover (207 a), the separation plate (207 c) is arc-shaped, the separation plate (207 c) is fixedly connected to the inside of the circulation groove (207 f), and the separation plate (207 c) is located below the gas outlet (207 b);

the separation cover (207 a) and the guide cover (207 d) are fixedly connected below the inner wall of the placing groove (102), the other end of the guide cover (207 d) is communicated with the element installation groove (106), the air inlet of the guide cover (207 d) is communicated with the outlet of the heat dissipation conduit (104 b), and the air outlet of the guide cover (207 d) is communicated with the sealing cover (105 a).