CN220271296U - Water quality parameter monitoring device - Google Patents

Abstract

The utility model relates to the technical field of water quality detection, in particular to a water quality parameter monitoring device. A water quality parameter monitoring device comprises a detection main body for detecting water quality, a sample platform, a sampling tube and a driving assembly, wherein the sample platform is provided with a plurality of container bottles filled with samples, the driving component is used for driving the sampling tube or/and the sample platform to move so that one end of the sampling tube can extend into the container bottles respectively, the other end of the sampling tube is communicated with the detection main body through the liquid adding pump, and the driving component is connected with the sampling tube or/and the sample platform. According to the utility model, the sampling tube and/or the sample platform are driven to move by the driving assembly, so that the detection main body can sequentially detect water samples to be detected in different container bottles, and the labor is saved.

Description

Water quality parameter monitoring device

Technical Field

The utility model relates to the technical field of water quality detection, in particular to a water quality detection method, relates to a water quality parameter monitoring device.

Background

In the aquatic product cultivation process, the contents of ammonia nitrogen, nitrite, calcium, magnesium, total alkalinity and the like in a water body are required to be detected frequently, when a plurality of water samples are required to be detected one by one, the detection flow of the existing water quality detection device adopts a mode that each water sample is poured into the water quality detection device for detection by one detector, and the detection mode can detect each water sample, but needs to consume a large amount of manpower to detect each water sample, so that the problem of high labor cost exists.

The prior art scheme discloses a water quality testing device for aquatic products is bred, including servo motor, servo motor top and axis of rotation bottom fixed connection, axis of rotation upper end and a conical gear fixed connection, a conical gear left end and two conical gear bottom meshing, two conical gear left ends and No. two axis of rotation fixed connection, no. two axis of rotation left ends are provided with power device, power device left side lower extreme and a connecting rod right-hand member fixed connection, a connecting rod left end and a slide bar right-hand member outer wall fixed connection, an axis of rotation passes through the belt and is connected with No. three axis of rotation, no. three axis of rotation top is provided with cleaning device, cleaning device and detection test tube left and right sides end inner wall swing joint, detection test tube left side lower extreme is provided with the blowdown lid, the blowdown lid left end is provided with switching device, no. three axis of rotation bottom and device shell bottom inner wall rotation are connected.

The technical scheme of this disclosure is through being provided with cleaning device, can drive power device up-and-down reciprocating motion through servo motor, and then drive cleaning device and carry out the back-and-forth motion and clean the detection test tube after detecting, has guaranteed detection quality. However, when a plurality of water samples are required to be detected, the disclosed technical scheme needs to pour the water samples into the detection device one by one manually, and the problem of high labor cost still exists.

Disclosure of Invention

The utility model provides a water quality parameter monitoring device, which aims to overcome the problem that in the prior art, when a detection device detects a plurality of water samples, manpower is wasted.

In order to solve the technical problems, the utility model adopts the following technical scheme: the utility model provides a quality of water parameter monitoring devices, includes detection main part, sample platform, sampling tube and the drive assembly that is used for detecting quality of water, be equipped with a plurality of container bottles that hold the sample on the sample platform, drive assembly is used for the drive sampling tube or/and sample platform motion so that the one end of sampling tube can stretch into a plurality of respectively in the container bottle, the other end of sampling tube pass through the charge pump with the detection main part is linked together, drive assembly with sampling tube or/and sample platform links to each other.

In the technical scheme, an operator places a plurality of water samples to be detected on a sample platform, and a driving device drives a sampling tube or/and the sample platform to move, so that the sampling tube stretches into each container bottle containing the water sample to be detected one by one, and then the water sample to be detected is pumped into a detection main body through a liquid adding pump, so that each water sample is detected sequentially. This technical scheme simple structure drives sampling tube and/or sample platform through drive assembly and removes, and then can make the detection main part detect the water sample that awaits measuring in the different container bottles in proper order, has saved the manpower, is favorable to the aquaculture personnel to wholly hold the change condition of quality of water, and then makes things convenient for aquaculture personnel to further guide the aquatic products appearance operation.

Preferably, the driving assembly comprises a first driving device and a second driving device, the first driving device drives the sample platform to rotate around the central axis of the vertical direction of the sample platform, and the second driving device drives the sampling tube to move up and down along the detection main body. In this technical scheme, first drive arrangement is located sample platform's below, second drive arrangement and sampling tube are located sample device's top, first drive arrangement is when driving sample platform rotation, every container bottle on the sample platform can rotate under the sampling tube, when needs sample, second drive arrangement drives the sampling tube and moves down along detecting the main part, and then make the sampling tube insert in the container bottle near sample platform's one end, and then in with the water sample suction to detect the main part that awaits measuring through the charge pump, after accomplishing this water sample detection, second drive arrangement drives the sampling tube upward movement and keeps away from the container bottle, then first drive arrangement drives sample platform rotation, and make another container bottle remove under the sampling tube, then sample to every container bottle in proper order.

Preferably, the sample platform is provided with a plurality of placement areas, and the placement areas form a circle or an ellipse. In this technical scheme, sample platform is circular or oval, can make things convenient for first drive arrangement to drive sample platform rotatory like this, places the district and is used for preventing the container bottle, for preventing that first drive arrangement from falling from sample platform when driving sample platform rotation, is provided with the structure that increases friction between container bottle and the sample platform on placing the district, places the district in addition and also can be groove structure, and the container bottle prevents also can prevent in groove structure that the container bottle from throwing away from placing the district.

Preferably, the first driving device comprises a first driving motor, and the sample platform is fixedly installed on an output shaft of the first driving motor. In this technical scheme, first drive arrangement still includes timing module, and timing module is connected with first driving motor electricity, and the operating personnel can control how long work once of first driving motor through timing module promptly, can control how long in proper order can work simultaneously first driving motor, in addition, still is provided with decelerator between first driving motor and the sample platform, can make the sample platform rotatable more steady like this.

Preferably, the second driving means comprises a cylinder, the telescopic rod of the cylinder is connected with the sampling tube. In this technical scheme, the cylinder is fixed at the top of detecting the main part, and the telescopic link is provided with the fixed block with the one end that the sampling tube links to each other, and the sampling tube is fixed on the fixed block, and the fixed block has certain width, and the sampling tube is located the fixed block and keeps away from the one end of detecting the main part, can avoid sample platform to hit down the detection main part when rotating like this.

Preferably, the second driving device comprises a second driving motor and a movable block, the movable block is installed on an output shaft of the second driving motor and is in threaded connection with the output shaft of the second driving motor, and the sampling tube is connected with the movable block. In the technical proposal, the second driving motor is arranged at the top of the detection main body, the bottom of the detection main body is provided with a bearing seat corresponding to the output shaft of the second driving motor, the output shaft of the second driving motor is arranged in the bearing seat, the positive and negative rotation of the second driving motor can drive the movable block to reciprocate on the output shaft of the second driving motor, so that the movable block can sample water samples to be detected in different container bottles.

Preferably, the sampling tube is a hose, and the length of the sampling tube between the liquid adding pump and the movable block is greater than the distance between the liquid adding pump and the second driving motor. In this technical scheme, the setting of hose can make the sampling tube have certain bending capability, and the length setting of hose can avoid the movable block to draw off the removal pipe when driving the sampling tube and remove simultaneously.

Preferably, the method comprises the steps of, and a sampling joint convenient for sampling is arranged at one end of the sampling tube, which is close to the sample platform. In this technical scheme, the sampling joint is L shape structure, can make things convenient for the sampling tube water intaking like this.

Preferably, the detection main body comprises a detection module and a flow channel which are communicated, one end of the circulation groove is communicated with the liquid adding pump through a pipeline, and the other end of the circulation groove is communicated with a drain pipe. In the technical scheme, the detection module can carry out all-round detection on water quality, and the detection module comprises but is not limited to turbidity detection, PH detection and chlorine detection.

Preferably, a communication module which can be electrically connected with an external platform is arranged in the detection main body. In the technical scheme, the communication module is Bluetooth communication, and an operator can operate the detection main body and complete checking of detection results through a mobile phone or other intelligent equipment.

Compared with the prior art, the utility model has the beneficial effects that:

in this embodiment, the operator places a plurality of water samples that need to detect on sample platform, and drive arrangement makes the sampling tube stretch into each container bottle that holds the water sample that awaits measuring one by one through driving sampling tube or/and sample platform remove, then pumps the water sample that awaits measuring into the detection main part through the charge pump, and then detects every water sample in proper order. The embodiment has simple structure, can detect a plurality of water samples to be detected through the driving device and the detection main body, saves manpower, is favorable to the aquaculture personnel to wholly grasp the change condition of water quality, and then makes things convenient for the aquaculture personnel to further guide the operation of aquatic product appearance.

Drawings

FIG. 1 is a schematic diagram of a water quality parameter monitoring apparatus according to an embodiment 1 of the present utility model;

FIG. 2 is a schematic diagram showing the connection relationship between a detecting body and a sampling tube in the water quality parameter monitoring device of the present utility model;

FIG. 3 is a schematic structural diagram of an embodiment 2 of the water quality parameter monitoring device of the present utility model;

FIG. 4 is a schematic diagram of the structure of a sample platform in the water quality parameter monitoring device of the present utility model.

In the accompanying drawings: 1. a detection body; 2. a drive assembly; 3. a sample platform; 4. a sampling tube; 5. a container bottle; 6. a liquid adding pump; 7. a sampling joint; 8. a placement area; 11. a detection module; 12. a flow channel; 13. a drain pipe; 21. a first driving motor; 22. a second driving motor; 23. a movable block; 24. and (3) a cylinder.

Detailed Description

The drawings are for illustrative purposes only and are not to be construed as limiting the present patent; for the purpose of better illustrating the embodiments, certain elements of the drawings may be omitted, enlarged or reduced and do not represent the actual product dimensions; it will be appreciated by those skilled in the art that certain well-known structures in the drawings and descriptions thereof may be omitted. The positional relationship depicted in the drawings is for illustrative purposes only and is not to be construed as limiting the present patent.

The same or similar reference numbers in the drawings of embodiments of the utility model correspond to the same or similar components; in the description of the present utility model, it should be understood that, if there are orientations or positional relationships indicated by terms "upper", "lower", "left", "right", "long", "short", etc., based on the orientations or positional relationships shown in the drawings, this is merely for convenience in describing the present utility model and simplifying the description, and is not an indication or suggestion that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, so that the terms describing the positional relationships in the drawings are merely for exemplary illustration and are not to be construed as limitations of the present patent, and that it is possible for those of ordinary skill in the art to understand the specific meaning of the terms described above according to specific circumstances.

The technical scheme of the utility model is further specifically described by the following specific embodiments with reference to the accompanying drawings:

example 1

As shown in fig. 1 to 4, a water quality parameter monitoring device comprises a detection main body 1 for detecting water quality, a sample platform 3, a sampling tube 4 and a driving component 2, wherein a plurality of container bottles 5 for containing samples are arranged on the sample platform 3, the driving component 2 is used for driving the sampling tube 4 or/and the sample platform 3 to move so that one end of the sampling tube 4 can respectively extend into the plurality of container bottles 5, the other end of the sampling tube 4 is communicated with the detection main body 1 through a liquid adding pump 6, and the driving component 2 is connected with the sampling tube 4 or/and the sample platform 3. In this embodiment, an operator places a plurality of water samples to be detected on the sample platform 3, and the driving device drives the sampling tube 4 or/and the sample platform 3 to move, so that the sampling tube 4 is communicated with each container bottle 5 containing the water sample to be detected one by one, and then the water sample to be detected is pumped into the detection main body 1 through the liquid adding pump 6, so that each water sample is detected in sequence. The embodiment has simple structure, the sampling tube 4 and/or the sample platform 3 are/is driven by the driving component 2 to move, so that the detection main body 1 can sequentially detect water samples to be detected in different container bottles 5, manpower is saved, the whole water quality change condition of aquaculture personnel is facilitated to be mastered, and further the aquaculture personnel can conveniently further guide the operation of the water quality.

The driving assembly 2 comprises a first driving device and a second driving device, the first driving device drives the sample platform 3 to rotate around the central axis of the vertical direction of the sample platform, and the second driving device drives the sampling tube 4 to move up and down along the detection main body 1. In this embodiment, the first driving device is located below the sample platform 3, the second driving device and the sampling tube 4 are located above the sample device, when the first driving device drives the sample platform 3 to rotate, each container bottle 5 on the sample platform 3 can rotate to be right below the sampling tube 4, when sampling is needed, the second driving device drives the sampling tube 4 to move downwards along the detection main body 1, so that one end of the sampling tube 4 close to the sample platform 3 is inserted into the container bottle 5, the water sample to be detected is pumped into the detection main body 1 through the liquid adding pump 6, after the water sample detection is completed, the second driving device drives the sampling tube 4 to move upwards and away from the container bottle 5, then the first driving device drives the sample platform 3 to rotate, and enables the other container bottle 5 to move to be right below the sampling tube 4, and then samples are sequentially taken out of each container bottle 5.

In addition, a plurality of placement areas 8 are arranged on the sample platform 3, and the placement areas 8 form a circle or an ellipse. In this embodiment, the sample platform 3 is circular or oval, can make things convenient for first drive arrangement to drive sample platform 3 rotatory like this, place district 8 and be used for preventing container bottle 5, for preventing that first drive arrangement from falling from sample platform 3 when driving sample platform 3 rotatory container bottle 5, place and be provided with the structure that increases friction between container bottle 5 and the sample platform 3 on the district 8, place district 8 in addition and also can be the groove structure, container bottle 5 prevents also can prevent in the groove structure that container bottle 5 from throwing away from placing district 8.

The first driving device comprises a first driving motor 21, and the sample platform 3 is fixedly arranged on an output shaft of the first driving motor 21. In this embodiment, the first driving device further includes a timing module, and the timing module is electrically connected with the first driving motor 21, that is, an operator can control how long the first driving motor 21 works once through the timing module, and can control how long the first driving motor 21 can work in sequence at the same time, and in addition, a speed reducer is further disposed between the first driving motor 21 and the sample platform 3, so that the sample platform 3 can rotate more stably.

In addition, the second driving device comprises a second driving motor 22 and a movable block 23, wherein the movable block 23 is arranged on the output shaft of the second driving motor 22 and is in threaded connection with the output shaft of the second driving motor, and the sampling tube 4 is connected with the movable block 23. In this embodiment, the second driving motor 22 is disposed at the top of the detecting body 1, a bearing seat corresponding to the output shaft of the second driving motor 22 is disposed at the bottom of the detecting body 1, the output shaft of the second driving motor 22 is mounted in the bearing seat, and the forward and reverse rotation of the second driving motor 22 can drive the movable block 23 to reciprocate on the output shaft of the second driving motor 22, so that the movable block 23 can sample the water samples to be detected in different container bottles 5.

Wherein, sampling tube 4 is the hose, and the length of sampling tube 4 is greater than the distance between liquid feeding pump 6 and the second driving motor 22 between liquid feeding pump 6 and the movable block 23. In this embodiment, the flexible tube is arranged to enable the sampling tube 4 to have a certain bending capability, and the length of the flexible tube is arranged to avoid the movable block 23 from breaking the movable tube when the sampling tube 4 is driven to move.

In addition, the detection main body 1 includes a detection module 11 and a flow channel 12 which are connected to each other, one end of the flow channel 12 is connected to the liquid feeding pump 6 through a pipe, and the other end is connected to a drain pipe 13. In this embodiment, the detection module 11 can perform all-round detection on water quality, and the detection module 11 includes, but is not limited to, turbidity detection, PH detection, and chlorine detection.

In addition, a communication module that can be electrically connected to an external platform is provided in the detection body 1. In this embodiment, the communication module is bluetooth communication, and an operator can operate the detection main body 1 and complete checking of the detection result through a mobile phone or other intelligent devices.

Example 2

In this embodiment, as shown in fig. 3, the second driving means comprises a cylinder 24, the telescopic rod of the cylinder 24 is connected with the sampling tube 4. In this embodiment, the cylinder 24 is fixed at the top of the detecting body 1, one end of the telescopic rod connected with the sampling tube 4 is provided with a fixing block, the sampling tube 4 is fixed on the fixing block, the fixing block has a certain width, and the sampling tube 4 is located at one end of the fixing block far away from the detecting body 1, so that the sample platform 3 can be prevented from knocking over the detecting body 1 during rotation.

Example 3

In this embodiment, the sampling tube 4 is provided with a sampling connector 7 at its end adjacent to the sample platform 3 for facilitating sampling. In this embodiment, the sampling connector 7 has an L-shaped structure, so that the sampling tube 4 can take water conveniently.

It is to be understood that the above examples of the present utility model are provided by way of illustration only and not by way of limitation of the embodiments of the present utility model. Other variations or modifications of the above teachings will be apparent to those of ordinary skill in the art. It is not necessary here nor is it exhaustive of all embodiments. Any modification, equivalent replacement, improvement, etc. which come within the spirit and principles of the utility model are desired to be protected by the following claims.

Claims (9)

1. A water quality parameter monitoring device is characterized in that: the water quality detection device comprises a detection main body (1) for detecting water quality, a sample platform (3), a sampling tube (4) and a driving assembly (2), wherein a plurality of container bottles (5) filled with samples are arranged on the sample platform (3), the driving assembly (2) is used for driving the sampling tube (4) or/and the sample platform (3) to move so that one end of the sampling tube (4) can extend into the plurality of container bottles (5) respectively, the other end of the sampling tube (4) is communicated with the detection main body (1) through a liquid adding pump (6), and the driving assembly (2) is connected with the sampling tube (4) or/and the sample platform (3); the driving assembly (2) comprises a first driving device and a second driving device, the first driving device drives the sample platform (3) to rotate around the central axis of the vertical direction of the sample platform, and the second driving device drives the sampling tube (4) to move up and down along the detection main body (1).

2. The water quality parameter monitoring device of claim 1, wherein: a plurality of placement areas (8) are arranged on the sample platform (3), and the placement areas (8) form a circle or an ellipse.

3. The water quality parameter monitoring device according to claim 1 or 2, characterized in that: the first driving device comprises a first driving motor (21), and the sample platform (3) is fixedly arranged on an output shaft of the first driving motor (21).

4. The water quality parameter monitoring device of claim 1, wherein: the second driving device comprises an air cylinder (24), and a telescopic rod of the air cylinder (24) is connected with the sampling tube (4).

5. The water quality parameter monitoring device of claim 1, wherein: the second driving device comprises a second driving motor (22) and a movable block (23), the movable block (23) is installed on an output shaft of the second driving motor (22) and is in threaded connection with the output shaft, and the sampling tube (4) is connected with the movable block (23).

6. The water quality parameter monitoring device of claim 5, wherein: the sampling tube (4) is a hose, and the length of the sampling tube (4) between the liquid adding pump (6) and the movable block (23) is greater than the distance between the liquid adding pump (6) and the second driving motor (22).

7. The water quality parameter monitoring device of claim 1, wherein: one end of the sampling tube (4) close to the sample platform (3) is provided with a sampling joint (7) which is convenient for sampling.

8. The water quality parameter monitoring device of claim 1, wherein: the detection main body (1) comprises a detection module (11) and a circulation groove (12) which are communicated, one end of the circulation groove (12) is communicated with the liquid adding pump (6) through a pipeline, and the other end of the circulation groove is communicated with a drain pipe (13).

9. The water quality parameter monitoring device of claim 1, wherein: the detection main body (1) is internally provided with a communication module which can be electrically connected with an external platform.