CN219830435U - Water quality monitoring sampling equipment - Google Patents

Abstract

The utility model relates to the technical field of water quality monitoring and sampling, in particular to water quality monitoring and sampling equipment, which comprises a floating ship body, a remote control box and a driving propeller, wherein the remote control box is arranged on the floating ship body; the working assembly comprises a fixed frame, a driving frame, a suction pipe, a water pump, a delivery pipe, a collecting component, a driving component and a reversing component; the fixing frame is fixedly connected with the floating ship body, the driving frame is in sliding connection with the fixing frame and penetrates through the floating ship body, the suction pipe is connected with the driving frame, the water pump is connected with the suction pipe, the delivery pipe is connected with the water pump, the collecting member is connected with the floating ship body, the driving member is connected with the fixing frame, the reversing member is connected with the floating ship body, and water samples of different depths can be extracted according to actual sampling requirements through the member.

Description

Water quality monitoring sampling equipment

Technical Field

The utility model relates to the technical field of water quality monitoring and sampling, in particular to water quality monitoring and sampling equipment.

Background

The water quality monitoring is a process of evaluating the water quality condition, and the water quality monitoring generally needs to be sampled in a designated water area, and in the past, the water quality monitoring is directly sampled by a detector when the detector reaches the river, so that the condition of falling into water is easy to occur.

The existing sampling equipment generally pumps water in a water area to a corresponding storage container through a water pump or a suction pipe, so that the whole sampling process is safer.

But adopt above-mentioned mode, can't adjust the degree of depth of taking a sample according to actual need when current sampling equipment takes a sample, lead to unable accurate water sample to appointed degree of depth to gather for comparatively inconvenient in the in-service use.

Disclosure of Invention

The utility model aims to provide water quality monitoring sampling equipment, which can extract water samples with different depths according to actual sampling requirements through components, so that the water quality monitoring sampling equipment is more convenient and faster in actual operation.

In order to achieve the above purpose, the utility model provides a water quality monitoring and sampling device, which comprises a floating hull, a remote control box and a driving screw, wherein the remote control box is installed on the floating hull, and the driving screw is electrically connected with the remote control box and is installed on one side of the floating hull, and the water quality monitoring and sampling device further comprises a working assembly;

the working assembly comprises a fixing frame, a driving frame, a suction pipe, a water pump, a delivery pipe, a collecting component, a driving component and a reversing component; the utility model discloses a ship, including floating hull, fixed frame, driving frame, reversing component, water pump, remote control box, collection component, drive component, remote control box, floating hull, fixed frame with floating hull fixed connection, be located floating hull one side, drive the frame with fixing frame sliding connection, run through floating hull, the suction tube with drive the frame and be located drive one side of frame, the water pump with the suction tube is connected, and with the remote control box electricity is connected, and fixed mounting is in one side of floating hull, the delivery tube with the water pump is connected, and fixed mounting is in one side of floating hull, the collection component with floating hull is connected, the drive component with the fixed frame is connected, the reversing component with floating hull is connected.

The collecting member comprises a placing frame, an outflow pipe, a connecting pipe, a containing bottle and a diverting component, wherein the placing frame is fixedly connected with the floating ship body and is positioned at one side of the floating ship body; the outflow pipe is connected with the delivery pipe and is positioned at one side of the delivery pipe; the connecting pipe is connected with the outflow pipe and is positioned at one side of the outflow pipe; the storage bottle is connected with the connecting pipe and is placed in the placing frame; the shunt member is connected to the delivery tube.

The driving component comprises a lifting screw and a lifting motor, wherein the lifting screw is in threaded connection with the driving frame and is rotatably arranged on one side of the fixing frame; the output shaft of the lifting motor is connected with the lifting screw, and the lifting motor is electrically connected with the remote control box and fixedly arranged on one side of the fixing frame.

The shunt part comprises a driving shaft, a unidirectional flow ring and a driving motor, wherein the driving shaft is rotationally connected with the delivery pipe and is positioned at one side of the delivery pipe; the unidirectional flow ring is fixedly connected with the driving shaft and is rotatably arranged in the delivery pipe; the output shaft of the driving motor is connected with the driving shaft, and the driving motor is electrically connected with the remote control box and fixedly arranged on one side of the eduction tube.

The reversing component comprises a rotating shaft, a drainage plate and a rotating motor, wherein the rotating shaft is rotationally connected with the floating ship body and is positioned on one side of the floating ship body; the drainage plate is fixedly connected with the rotating shaft and is positioned at one side of the rotating shaft; the output shaft of the rotating motor is connected with the rotating shaft, and the rotating motor is electrically connected with the remote control box and fixedly arranged on one side of the floating ship body.

According to the water quality monitoring sampling equipment, the driving screw is driven by the remote control box, so that the floating ship body can move on the water surface under the driving of the driving screw, after a corresponding area is moved, the lifting motor can be controlled to drive by the remote control box, the lifting screw is driven by the lifting motor to rotate, the driving frame is driven to move downwards by the rotation of the lifting screw, the sampling depth of the absorption end of the suction tube is adjusted by the depth of the downward movement of the driving frame, then the water sample at the bottom absorption end of the suction tube is absorbed by the water pump, then the water sample passes through the outflow tube and the connecting tube and is guided into the storage bottle by the delivery tube, after the sampling of the water sample at one depth is finished, the height of the driving frame can be adjusted again, then the driving shaft and the one-way flow ring are driven by the driving motor to rotate in the delivery tube, the outflow slot of the one-way flow and the other side of the delivery ring are enabled to move downwards, the water sample can be conveniently and effectively sampled by the water sample at the same depth as the same time, and the water sample can not be sampled by the water sample in the storage bottle.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below.

FIG. 1 is a schematic view showing the overall structure of a water quality monitoring and sampling apparatus according to a first embodiment of the present utility model.

Fig. 2 is a schematic view of the mounting structure of the rack according to the first embodiment of the present utility model.

Fig. 3 is a schematic view of the mounting structure of the unidirectional flow ring of the first embodiment of the present utility model.

Fig. 4 is a schematic cross-sectional view of a unidirectional flow ring of a first embodiment of the utility model.

FIG. 5 is a schematic view showing the overall structure of a water quality monitoring and sampling device according to a second embodiment of the present utility model.

In the figure: 101-floating ship body, 102-remote control box, 103-driving propeller, 104-fixing frame, 105-driving frame, 106-suction tube, 107-water pump, 108-delivery tube, 109-placing frame, 110-outflow tube, 111-connecting tube, 112-containing bottle, 113-lifting screw, 114-lifting motor, 115-driving shaft, 116-unidirectional flow ring, 117-driving motor, 201-rotating shaft, 202-drainage plate and 203-rotating motor.

Detailed Description

The following detailed description of embodiments of the utility model, examples of which are illustrated in the accompanying drawings and, by way of example, are intended to be illustrative, and not to be construed as limiting, of the utility model.

The first embodiment of the utility model is as follows:

referring to fig. 1 to 4, fig. 1 is a schematic structural diagram of an overall water quality monitoring and sampling apparatus, fig. 2 is a schematic structural diagram of a mounting structure of a rack 109, fig. 3 is a schematic structural diagram of a mounting structure of a unidirectional flow ring 116, and fig. 4 is a schematic sectional structural diagram of the unidirectional flow ring 116.

The utility model provides water quality monitoring sampling equipment, which comprises: including floating hull 101, remote control box 102, drive screw 103 and work subassembly, work subassembly includes mount 104, drive frame 105, suction tube 106, water pump 107, delivery tube 108, collection component, drive component and switching-over component, collection component includes rack 109, outlet pipe 110, connecting pipe 111, accomodates bottle 112 and reposition of redundant personnel part, drive component includes elevating screw 113 and elevator motor 114, the reposition of redundant personnel part includes drive shaft 115, unidirectional flow ring 116 and driving motor 117, has solved the degree of depth of can't carrying out the regulation to the sample according to actual need when current sampling equipment takes a sample through the aforesaid scheme, leads to unable accurate water sample to the appointed degree of depth to gather for comparatively inconvenient problem in the in-service use, it can be understood that the aforesaid scheme can be used in current sampling equipment when taking a sample, can't adjust the degree of depth of taking a sample, makes the very inconvenient condition when taking a sample.

In this embodiment, the remote control box 102 is mounted on the floating hull 101, the driving propeller 103 is electrically connected with the remote control box 102, and is mounted on one side of the floating hull 101, the remote control box 102 is an existing remote control electronic template, the driving propeller 103 is mounted at the bottom of the floating hull 101, the driving propeller 103 is provided with a propeller rotating device and a driving device for driving the propeller to rotate, and meanwhile, the driving device is also connected with the remote control box 102 through a corresponding control circuit, and the operation of the driving propeller 103 can be completed through the remote control box 102, and since the remote control box 102 and the driving propeller 103 are all of a very mature prior art, the detailed description is omitted in this scheme.

The fixed frame 104 is fixedly connected with the floating hull 101 and is positioned at one side of the floating hull 101, the driving frame 105 is slidably connected with the fixed frame 104 and penetrates through the floating hull 101, the suction pipe 106 is connected with the driving frame 105 and is positioned at one side of the driving frame 105, the water pump 107 is connected with the suction pipe 106 and is electrically connected with the remote control box 102 and is fixedly arranged at one side of the floating hull 101, the delivery pipe 108 is connected with the water pump 107 and is fixedly arranged at one side of the floating hull 101, the collecting member is connected with the floating hull 101, the driving member is connected with the fixed frame 104, the reversing member is connected with the floating hull 101, the lifting screw 113 is in threaded connection with the driving frame 105 and is rotatably arranged at one side of the fixed frame 104. The output shaft of the lifting motor 114 is connected with the lifting screw 113, the lifting motor 114 is electrically connected with the remote control box 102 and is fixedly installed on one side of the fixed frame 104, the fixed frame 104 is fixedly installed on the top of the floating hull 101, the driving frame 105 is a square cylinder, the floating hull 101 is provided with a sliding groove for the driving frame 105 to slide up and down, the suction pipe 106 is buried in the driving frame 105, two ends of the suction pipe 106 are respectively positioned at the upper end and the lower end of the driving frame 105, the upper end of the suction pipe 106 is communicated with the water inlet end of the water pump 107, the suction pipe 106 is provided with a reserved length on one side connected with the water pump 107, so that when the suction pipe 106 is driven by the driving frame 105 to slide down, the water pump 107 and the suction pipe 106 can be kept normally connected, the water outlet end of the water pump 107 is provided with the delivery pipe 108, the delivery pipe 108 is installed on the fixed frame of the floating hull 101 through the floating hull 101, the two ends of the suction pipe 106 are respectively positioned at the upper end and lower end of the driving frame 105, the lifting motor is connected with the lifting screw 113 through the corresponding lifting screw 114, the lifting screw is also connected with the lifting screw 113, the lifting screw is driven by the lifting frame 113, the lifting screw is driven by the lifting screw 113, and the lifting screw is driven by the lifting screw 113 to rotate the lifting screw 105, and the lifting screw is matched with the lifting screw 113 to rotate the lifting screw 113 to move the lifting screw 105, and the lifting screw 105 is driven by the lifting screw 105 to move the lifting screw. So that the user can perform corresponding operations on the lifting motor 114 and the water pump 107.

Secondly, the rack 109 is fixedly connected to the floating hull 101 and located at one side of the floating hull 101; the outflow tube 110 is connected to the delivery tube 108 and is located on one side of the delivery tube 108; the connection pipe 111 is connected to the outflow pipe 110 and is located at one side of the outflow pipe 110; the storage bottle 112 is connected with the connecting pipe 111 and placed in the placing frame 109; the shunt is connected to the delivery tube 108, and the driving shaft 115 is rotatably connected to the delivery tube 108 and located at one side of the delivery tube 108; the unidirectional flow ring 116 is fixedly connected with the driving shaft 115 and is rotatably installed in the delivery tube 108; the output shaft of the driving motor 117 is connected with the driving shaft 115, the driving motor 117 is electrically connected with the remote control box 102 and is fixedly installed at one side of the delivery pipe 108, the two placing frames 109 are respectively installed at two sides of the floating ship body 101, the two placing frames 109 are respectively provided with two containing bottles 112, the two containing bottles 112 are respectively connected with the outflow pipes 110 correspondingly installed at two sides of the delivery pipe 108 through the two connecting pipes 111, the unidirectional flow ring 116 is further arranged in the delivery pipe 108, the driving shaft 115 is fixedly installed at the bottom of the unidirectional flow ring 116, the driving shaft 115 is fixed with the output shaft of the driving motor 117, the driving motor 117 is connected with the remote control box 102 through corresponding circuits, so that a user can drive the driving shaft 115 and the unidirectional flow ring 116 to rotate through controlling the driving motor 117, the inside of the unidirectional flow ring 116 is provided with an L-shaped flow groove, the flow groove at the side of the unidirectional flow ring 116 is matched with the pipe diameter of the outflow pipe 110, when the outflow pipe 110 is correspondingly matched with the corresponding outflow pipe 110, the unidirectional flow ring 116 can be blocked by the unidirectional flow ring 110 when the outflow pipe 110 is correspondingly arranged at the side of the outflow pipe 110.

When the water quality monitoring sampling device is used, the remote control box 102 drives the driving screw 103, so that the floating ship body 101 can be driven by the driving screw 103 to move on the water surface, after a corresponding area is moved, the remote control box 102 can control the lifting motor 114 to drive, the lifting motor 114 can drive the lifting screw 113 to rotate, thereby the driving shaft 115 and the one-way guide shaft 116 are driven to move downwards through the rotation of the lifting screw 113, the sampling depth of the absorption end of the suction tube 106 is adjusted through the depth of the downward movement of the driving shaft 105, then the water sample at the bottom absorption end of the suction tube 106 is absorbed through the water pump 107, then the water sample passes through the outflow tube 110 and the connecting tube 111 to be guided into the storage bottle 112, after the water sample at one depth is sampled, the height of the driving shaft 105 can be adjusted again, then the driving motor can drive the driving shaft 115 and the one-way guide shaft 116 to rotate, the water sample can not be led into the storage bottle 112 through the guide tube 108, and the water sample can be conveniently pulled into the other side of the storage bottle 112 through the guide tube 116 according to the different depth, and the water sample can not be conveniently sampled by the water sample at the other side.

Second embodiment:

referring to fig. 5, fig. 5 is a schematic structural diagram of the whole water quality monitoring and sampling device according to the second embodiment, and the reversing component provided by the utility model includes a rotating shaft 201, a drainage plate 202 and a rotating motor 203.

Wherein the rotation shaft 201 is rotatably connected to the floating hull 101 and is located at one side of the floating hull 101; the drainage plate 202 is fixedly connected with the rotating shaft 201 and is positioned at one side of the rotating shaft 201; the output shaft of the rotating motor 203 is connected with the rotating shaft 201, the rotating motor 203 is electrically connected with the remote control box 102 and is fixedly installed on one side of the floating hull 101, the rotating shaft 201 is rotatably installed on the front side of the floating hull 101, the bottom of the rotating shaft 201 is fixedly provided with the drainage plate 202, meanwhile, the rotating shaft 201 is fixedly connected with the output shaft of the rotating motor 203, the rotating motor 203 is also connected with the remote control box 102 through a corresponding circuit, so that a user can operate the rotating motor 203 through the remote control box 102, and then when the floating hull 101 moves, the rotating shaft 201 and the drainage plate 202 are driven to rotate through the rotating motor 203, and steering when the floating hull 101 moves is completed through the rotation of the drainage plate 202.

When the water quality monitoring sampling device of the embodiment is used, the rotating shaft 201 can be driven to rotate through the rotating motor 203, and the drainage plate 202 can be driven to rotate when the rotating shaft 201 rotates, so that a user can change the moving direction of the floating ship body 101 through adjusting the angle of the drainage plate 202 when driving the floating ship body 101 to move on the water surface through the driving screw 103, and the practicability of the whole device is greatly enhanced.

The foregoing disclosure is only illustrative of one or more preferred embodiments of the present utility model, and it is not intended to limit the scope of the claims hereof, as persons of ordinary skill in the art will understand that all or part of the processes for practicing the embodiments described herein may be practiced with equivalent variations in the claims, which are within the scope of the utility model.

Claims (5)

1. The water quality monitoring and sampling equipment comprises a floating hull, a remote control box and a driving screw, wherein the remote control box is arranged on the floating hull, the driving screw is electrically connected with the remote control box and is arranged on one side of the floating hull,

the device also comprises a working assembly;

the working assembly comprises a fixing frame, a driving frame, a suction pipe, a water pump, a delivery pipe, a collecting component, a driving component and a reversing component; the utility model discloses a ship, including floating hull, fixed frame, driving frame, reversing component, water pump, remote control box, collection component, drive component, remote control box, floating hull, fixed frame with floating hull fixed connection, be located floating hull one side, drive the frame with fixing frame sliding connection, run through floating hull, the suction tube with drive the frame and be located drive one side of frame, the water pump with the suction tube is connected, and with the remote control box electricity is connected, and fixed mounting is in one side of floating hull, the delivery tube with the water pump is connected, and fixed mounting is in one side of floating hull, the collection component with floating hull is connected, the drive component with the fixed frame is connected, the reversing component with floating hull is connected.

2. A water quality monitoring sampling device according to claim 1, wherein,

the collecting member comprises a placing frame, an outflow pipe, a connecting pipe, a containing bottle and a diverting component, wherein the placing frame is fixedly connected with the floating ship body and is positioned at one side of the floating ship body; the outflow pipe is connected with the delivery pipe and is positioned at one side of the delivery pipe; the connecting pipe is connected with the outflow pipe and is positioned at one side of the outflow pipe; the storage bottle is connected with the connecting pipe and is placed in the placing frame; the shunt member is connected to the delivery tube.

3. A water quality monitoring sampling device according to claim 1, wherein,

the driving component comprises a lifting screw rod and a lifting motor, wherein the lifting screw rod is in threaded connection with the driving frame and is rotatably arranged on one side of the fixing frame; the output shaft of the lifting motor is connected with the lifting screw, and the lifting motor is electrically connected with the remote control box and fixedly arranged on one side of the fixing frame.

4. A water quality monitoring sampling device according to claim 2, wherein,

the shunt part comprises a driving shaft, a unidirectional flow ring and a driving motor, wherein the driving shaft is rotationally connected with the delivery pipe and is positioned at one side of the delivery pipe; the unidirectional flow ring is fixedly connected with the driving shaft and is rotatably arranged in the delivery pipe; the output shaft of the driving motor is connected with the driving shaft, and the driving motor is electrically connected with the remote control box and fixedly arranged on one side of the eduction tube.

5. A water quality monitoring sampling device according to claim 1, wherein,

the reversing component comprises a rotating shaft, a drainage plate and a rotating motor, wherein the rotating shaft is rotationally connected with the floating ship body and is positioned at one side of the floating ship body; the drainage plate is fixedly connected with the rotating shaft and is positioned at one side of the rotating shaft; the output shaft of the rotating motor is connected with the rotating shaft, and the rotating motor is electrically connected with the remote control box and fixedly arranged on one side of the floating ship body.