CN219348844U - Environmental engineering fresh water quality detection equipment - Google Patents

Abstract

The utility model discloses a device for detecting the quality of fresh water in environmental engineering, which is characterized by comprising the following components: the device comprises a circular shell, wherein a mounting groove is formed in the lower portion of the circular shell, suspended foam is fixed in the mounting groove, a fixing plate is fixed in the circular shell, a water pump is fixedly arranged above the fixing plate, a water inlet is formed in the lower input end of the water pump in a communicating mode, a water inlet is movably inserted into the water inlet, a plurality of sensors are fixedly arranged on the periphery of the water pump and above the fixing plate, a U-shaped frame is inversely arranged on the right side of the circular shell, a moving mechanism capable of driving the water inlet to move downwards is arranged on the fixing plate, samples at different positions can be adopted at the same water source, meanwhile, water source samples at different depths can be adopted in the same water source, detection inaccuracy is guaranteed, equipment cost is low, transportation is convenient, requirements on manpower and material resources are reduced, and water quality data of any river basin position in a river can be detected at any time.

Description

Environmental engineering fresh water quality detection equipment

Technical Field

The utility model relates to the technical field of water quality detection, in particular to environmental engineering fresh water quality detection equipment.

Background

Along with the progress of industry, the number of factories is drastically increased, so that the sewage discharge amount is continuously increased, and water pollution is more and more serious, for example, temperature, turbidity, PH value, conductivity, dissolved oxygen and the like of detected water quality are increased, and a small house is built on the shore for installing the detection equipment in a house or a water quality monitoring cabinet is built on the shore, and then a water intake pipe is extended into a river.

The existing fresh water quality detection equipment cannot take samples at different positions at the same water source, and meanwhile cannot take water source samples at different depths in the same water source, so that the detected samples are single, the detection is inaccurate, the existing sampling equipment is high in cost and inconvenient to transport, the requirements on manpower and material resources are very high, and water quality data of any river basin position in a river cannot be detected at any time.

Disclosure of Invention

The utility model aims to provide environmental engineering fresh water quality detection equipment which can solve at least one of the technical problems, and the technical scheme of the utility model is as follows:

an environmental engineering fresh water quality detection device, characterized by comprising: circular shell be equipped with the mounting groove circular shell below be fixed with suspension foam in the mounting groove circular shell internal fixation has the fixed plate fixed be equipped with the water pump above the fixed plate the water inlet is equipped with to water pump below input intercommunication the water inlet is last to be movably pegged graft has the water inlet the water pump is located fixed a plurality of sensors that are equipped with in fixed plate top all around circular shell right side inversion is equipped with the U-shaped frame be equipped with the mobile mechanism that can drive water inlet and move down on the fixed plate be equipped with the water diversion portion that can connect each sensor the U-shaped frame right side is equipped with the actuating mechanism that can drive circular shell and remove be equipped with steering unit on the U-shaped frame.

Further, the water inlet part comprises a connecting pipe movably inserted on the water inlet, and the lower end of the connecting pipe is respectively connected with a first filter tip and a second filter tip.

Further, the moving mechanism comprises a threaded sleeve fixed on one side of the connecting pipe, a first motor is fixed above the fixed plate, a screw is fixed at the output end of the first motor, and the screw is in threaded fit with the threaded sleeve.

Further, the water diversion part comprises a water flow device fixedly connected to the output end above the water pump, and a conveying pipe is connected between the water flow device and each sensor.

Further, the driving mechanism comprises a second motor fixed above the U-shaped frame, a first bevel gear is fixed at the output end of the second motor, an installation shell is fixed on the right side of the U-shaped frame, fan blades are movably inserted into the installation shell, a second bevel gear is fixed at the insertion end of each fan blade, an insertion shaft is longitudinally inserted into the installation shell, third bevel gears are fixed at the upper end and the lower end of each insertion shaft, and the third bevel gears which are arranged up and down are meshed with the first bevel gear and the second bevel gear respectively.

Further, the steering part comprises a push rod motor fixed above the fixed U-shaped frame, a steering plate is symmetrically and movably hinged on the mounting shell, a connecting block is fixed at the hinged end of the steering plate, connecting rods are hinged between the connecting blocks, and the output end of the push rod motor is connected with the connecting rods.

Preferably, a water outlet is connected below the sensor and penetrates through the fixing plate.

In summary, compared with the prior art, the utility model has the following beneficial effects:

the utility model provides a device for detecting the quality of fresh water in environmental engineering, which is characterized in that when in use, a user places a circular shell fixed with suspended foam through a mounting groove in a water area to be detected, at the moment, a water source is sucked into a water gap through a water pump, then the water source is conveyed to each sensor through a water dividing part for inspection, the inspected water source is discharged from a water outlet, when the water sources in different places need to be detected, the circular shell is moved to the required water area through a driving mechanism and a steering part, and when the water sources in different depths need to be detected, the water inlet part is driven by a moving mechanism to move downwards, so that the water sources in the water areas in different depths are input to the water pump.

Drawings

Fig. 1 is a perspective view of the present utility model.

FIG. 2 is one of the exploded views of the present utility model.

FIG. 3 is a second exploded view of the present utility model.

Reference numerals illustrate: 1. a circular housing; 2. a mounting groove; 3. suspending foam; 4. a fixing plate; 5. a water pump; 6. a water inlet; 7. a water inlet part; 8. a sensor; 9. a U-shaped frame; 100. a moving mechanism; 200. a water dividing part; 300. a driving mechanism; 400. a steering section; 71. a connecting pipe; 72. a first filter; 73. a second filter; 101. a thread sleeve; 102. a first motor; 103. a screw; 201. a water flow device; 202. a delivery tube; 301. a second motor; 302. a first bevel gear; 303. a mounting shell; 304. a fan blade; 305. a second bevel gear; 306. a plug-in shaft; 307. a third bevel gear; 401. a push rod motor; 402. a steering plate; 403. a connecting block; 404. a connecting rod; 81. and a water outlet.

Detailed Description

The utility model is further described in the following description and detailed description with reference to the drawings:

an environmental engineering fresh water quality detection apparatus as shown in fig. 1 to 3, comprising: circular shell 1 be equipped with mounting groove 2 circular shell 1 below mounting groove 2 internal fixation has suspension foam 3 circular shell 1 internal fixation has fixed plate 4 top is fixed and is equipped with water pump 5 below input intercommunication is equipped with water inlet 6 the activity is pegged graft on water inlet 6 water pump 5 is located fixed a plurality of sensors 8 in fixed plate 4 top all around circular shell 1 right side is invertedly equipped with U-shaped frame 9 be equipped with on the fixed plate 4 and can drive the mobile mechanism 100 of water inlet 7 down removal be equipped with the water diversion portion 200 that can connect each sensor 8 the actuating mechanism 300 that can drive circular shell 1 is equipped with on the right side of U-shaped frame 9 be equipped with steering unit 400 on the U-shaped frame 9.

The circular shell 1 with the suspended foam 3 fixed by the mounting groove 2 is placed in a water area to be detected by a user during use, at the moment, a water source is sucked into the water gap 6 by the water pump 5, the water source is conveyed to each sensor 8 through the water distribution part 200 for detection, the detected water source is discharged from the water outlet 81, when the water sources in different places need to be detected, the circular shell 1 is moved to the required water area by the driving mechanism 300 and the steering part 400, and when the water sources in different depths need to be detected, the water inlet part 7 is driven to move downwards by the moving mechanism 100, so that the water sources in the water areas in different depths are input to the water pump 5.

As shown in fig. 2 and 3, in some embodiments of the present utility model, the water inlet 7 includes a connecting pipe 71 movably inserted in the water inlet 6, a first filter tip 72 and a second filter tip 73 are respectively connected to the lower end of the connecting pipe 71, when the water inlet 7 inputs the water source into the water pump 5, the water source is filtered in multiple layers through the first filter tip 72 and the second filter tip 73, so as to ensure the accuracy of detection, and the filtered water source is input into the water pump 5 from the connecting pipe 71.

As shown in fig. 2 and 3, in some embodiments of the present utility model, in order to achieve the effect of driving the water inlet 7 to move downward, the moving mechanism 100 includes a threaded sleeve 101 fixed on one side of the connecting pipe 71, a first motor 102 is fixed above the fixing plate 4, and a screw 103 is fixed at an output end of the first motor 102, where the screw 103 is in threaded engagement with the threaded sleeve 101.

When the environmental engineering fresh water quality detection equipment adopting the structure is operated, the equipment is connected with the first motor 102 through a power supply, the output end of the first motor 102 drives the screw 103 to rotate at the moment, and the screw rotates to drive the connecting pipe 71 to move downwards through the threaded sleeve 101 fixed on one side of the connecting pipe 71, so that detection of different depths of a water source is achieved.

As shown in fig. 2 and 3, in some embodiments of the present utility model, in order to achieve the effect of driving the filtering portion 9 to move longitudinally, the water dividing portion 200 includes a water flow device 201 fixedly connected to an output end above the water pump 5, a delivery pipe 202 is connected between the water flow device 201 and each sensor 8, the water inlet portion 7 delivers water to the water pump 5, at this time, the water pump 5 delivers water to the water flow device 201, the water flow device 201 delivers water to each delivery pipe 202, and the delivery pipe 202 delivers water to the sensor 8.

As shown in fig. 2 and 3, in some embodiments of the present utility model, in order to achieve the effect of driving the circular housing 1 to move, the driving mechanism 300 includes a second motor 301 fixed above the U-shaped frame 9, a first bevel gear 302 is fixed at an output end of the second motor 301, a mounting case 303 is fixed at a right side of the U-shaped frame 9, a fan blade 304 is movably inserted into the mounting case 303, a second bevel gear 305 is fixed at an inserting end of the fan blade 304, an inserting shaft 306 is longitudinally inserted into the mounting case 303, third bevel gears 307 are fixed at upper and lower ends of the inserting shaft 306, and the third bevel gears 307 disposed up and down are meshed with the first bevel gear 302 and the second bevel gear 305 by 7, respectively.

When the environmental engineering fresh water quality detection device with the structure is operated, the device is connected with the second motor 301 through a power supply, at the moment, the output end of the second motor 301 drives the first bevel gear 302 to rotate, the first bevel gear 302 drives one of the third bevel gears 307 to rotate through driving the other third bevel gear 307 to rotate through the inserting shaft 306, the other third bevel gear 307 drives the second bevel gear 305 to rotate, and the second bevel gear 305 rotates to drive the fan blade 304 movably inserted into the mounting shell 303 to rotate.

As shown in fig. 2 and 3, in some embodiments of the present utility model, in order to achieve the effect of driving the circular housing 1 to steer, the steering unit 400 includes a push rod motor 401 fixed above the fixed U-shaped frame 9, a steering plate 402 movably hinged on the mounting housing 303 symmetrically, a connecting block 403 fixed on the hinged end of the steering plate 402, and a connecting rod 404 hinged between the connecting blocks 403, where the output end of the push rod motor 401 is connected with the connecting rod 404.

When the environmental engineering fresh water quality detection device with the structure is in operation, the connecting rod 404 is driven to move through the output end of the push rod motor 401, so that the connecting rod 404 drives the connecting blocks 403 to swing simultaneously, and the connecting blocks 403 swing the steering plate 402.

While there has been shown and described what is at present considered to be the fundamental principles and the main features of the utility model and the advantages thereof, it will be understood by those skilled in the art that the present utility model is not limited to the foregoing embodiments, but is described in the foregoing description merely illustrates the principles of the utility model, and various changes and modifications may be made therein without departing from the spirit and scope of the utility model as hereinafter claimed. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (7)

1. An environmental engineering fresh water quality detection device, characterized by comprising: circular shell (1) below is equipped with mounting groove (2) internal fixation has suspension foam (3) circular shell (1) internal fixation has fixed plate (4) fixed be equipped with water pump (5) in fixed plate (4) top water pump (5) below input intercommunication is equipped with water inlet (6) movable grafting has water inlet (7) on water pump (5) are located fixed a plurality of sensors (8) in fixed plate (4) top all around circular shell (1) right side inversion is equipped with U-shaped frame (9) be equipped with on fixed plate (4) can drive water inlet (7) downwardly moving's mobile mechanism (100) be equipped with water dividing part (200) that can connect each sensor (8) U-shaped frame (9) right side is equipped with and can drives circular shell (1) and remove actuating mechanism (300) U-shaped frame (9) are equipped with steering part (400).

2. The environmental engineering fresh water quality detection device according to claim 1, wherein the water inlet (7) comprises a connecting pipe (71) movably inserted on the water inlet (6), and a first filter tip (72) and a second filter tip (73) are respectively connected at the lower end of the connecting pipe (71).

3. The environmental engineering fresh water quality detection device according to claim 2, wherein the moving mechanism (100) comprises a threaded sleeve (101) fixed on one side of the connecting pipe (71), a first motor (102) is fixed above the fixed plate (4), a screw (103) is fixed at the output end of the first motor (102), and the screw (103) is in threaded fit with the threaded sleeve (101).

4. The environmental engineering fresh water quality detection device according to claim 1, wherein the water diversion portion (200) comprises a water flow device (201) fixedly connected to an output end above the water pump (5), and a conveying pipe (202) is connected between the water flow device (201) and each sensor (8).

5. The environmental engineering fresh water quality detection device according to claim 1, wherein the driving mechanism (300) comprises a second motor (301) fixed above a U-shaped frame (9), a first bevel gear (302) is fixed at the output end of the second motor (301), a mounting shell (303) is fixed on the right side of the U-shaped frame (9), a fan blade (304) is movably inserted into the mounting shell (303), a second bevel gear (305) is fixed at the inserting end of the fan blade (304), an inserting shaft (306) is longitudinally inserted into the mounting shell (303), third bevel gears (307) are fixed at the upper end and the lower end of the inserting shaft (306), and the third bevel gears (307) arranged up and down are meshed with the first bevel gear (302) and the second bevel gear (305) respectively.

6. The environmental engineering fresh water quality detection device according to claim 5, wherein the steering part (400) comprises a fixed U-shaped frame (9), a push rod motor (401) is fixed above the fixed U-shaped frame, a steering plate (402) is symmetrically and movably hinged to the mounting shell (303), a connecting block (403) is fixed at the hinged end of the steering plate (402), a connecting rod (404) is hinged between the connecting blocks (403), and the output end of the push rod motor (401) is connected with the connecting rod (404).

7. An environmental engineering fresh water quality inspection device according to claim 1, characterized in that a water outlet (81) is connected below the sensor (8) and through the fixed plate (4).

Images