KR20210047757A - Water collector - Google Patents

Abstract

The present invention relates to a water collector apparatus which comprises: one or more sample collection units (100) which respectively collect one or more types of fluid samples; one or more water collection containers (200) which store the fluid samples collected by the sample collection units (100); one or more automatic supply units (300) which introduce the fluid samples collected from the sample collection units (100) respectively into the water collection containers (200); and a disc-shaped rotary plate (400) which holds the one or more water collection containers (200). The rotary plate (400) rotates around a central rotary shaft in the clockwise or the counterclockwise direction. In accordance with the rotation of the rotary plate (400), the one or more water collection containers (200) held on the rotary plate (400) are connected to the automatic supply units (300). The present invention aims to provide the water collector apparatus which is able to automate the process of introducing and storing fluid samples.

Description

Water collector{Water collector}

The present invention relates to a water collection device, and more particularly, to a device capable of automatically collecting a fluid sample and easily storing at least one or more fluid samples collected in a water collection container.

As a pollutant source for domestic sewage and industrial wastewater polluting rivers, organic matter occupies most of the pollutants.

Measurement indicators of organic matter include COD (Chemical Oxygen Demand), BOD (Biological Oxygen Demand), and TOC (Total Organic Carbon). Currently, in Korea, COD and BOD measurements are used as complementary methods, but about 60% of organic matter While measuring accuracy, TOC can measure more than 90%, emerging as a new alternative to organic matter measurement indicators.

In addition, the importance of the TOC measuring device is more emphasized due to the inflow of non-degradable organic matter, long analysis time for BOD measurement, and problems of secondary pollutants in COD measurement.

In recent years, as part of real-time water pollution monitoring, at least one fluid sample is collected and each fluid sample collected in a laboratory is separated and stored, and the collection and storage of fluid samples is more than a method of measuring using fluid samples stored as needed. There is a growing need for this automated on-line water collection device.

According to Korean Patent No. 10-1229577, there is provided a method and apparatus for measuring total organic carbon that can improve accuracy while dramatically shortening the analysis time for a fluid sample having a wide range of concentrations.

However, the conventional measuring device as described above is manufactured focusing on the operation of one measuring device for one type of fluid sample rather than automating the collection and storage of one or more fluid samples using a single machine. In the case of automating the process of collecting and storing more than one type of fluid sample, there is a problem in that it requires a lot of cost because a plurality of measuring devices must be provided.

The present invention is to solve the above-described problem, and an automatic supply capable of allowing a sample collection unit to collect one or more types of fluid samples and one or more types of fluid samples collected from the sample collection unit to flow into a plurality of water collection containers, respectively. It is an object of the present invention to provide a sample collection device capable of automating introduction and storage of fluid samples, as well as allowing at least one or more types of fluid samples to be simultaneously introduced into each water collection container.

However, the object of the present invention is not limited to the above-mentioned object, and another object not mentioned will be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, the present invention provides one or more sample collection units 100 for each of at least one type of fluid sample; and one or more collection containers for storing fluid samples collected from the sample collection unit 100 ( 200); And at least one automatic supply unit 300 for each of the fluid samples collected from the sample collection unit 100 to flow into the water collection container 200; And one or more of the water collection container 200 is mounted in a circular plate shape. Including, the rotating plate 400; Including, separating the compartment with respect to the space on the upper surface of the rotating plate, one or more collection containers are located in each of the compartments, and different fluid samples for each compartment are stored in the collection container.

In addition, as the automatic supply units are provided in each of the compartments, different fluid samples are introduced into each compartment, and the compartment includes a plurality of compartments.

In the above, the rotating plate 400 separates partitions with respect to the space on the upper surface of the rotating plate, and at least one water collection container is located in each of the partitions, and different fluid samples are stored in the collection container for each partition, and the As each of the compartments is provided with an automatic supply unit, different fluid samples are introduced into each compartment, and the compartment includes a plurality of compartments.

In addition, the rotating plate 400 is rotated clockwise or counterclockwise with respect to a central rotation axis, but at least one water collecting container mounted on the rotating plate 400 according to the rotation of the rotating plate 400 ( 200) is connected to the automatic supply unit 300.

In addition, the sample collection unit 100 is a circulation pipe 110 through which the fluid is circulated; and a circulation pump 120 which induces circulation of the fluid by being connected to the circulation pipe 110; and the circulation pipe 110 Including, but the fluid circulated in the circulation pipe 110 is continuously supplied and discharged to the mini-chamber 130.

In addition, the mini-chamber 130 has a structure in which the internal space is sealed, and a housing 131 in which the fluid circulated in the circulation pipe 110 is filled in the internal space; and a fluid filled in the housing 131 Including, the housing 131 is a sample supply passage 140 provided to collect the fluid filled in the housing; characterized in that it is connected to.

In addition, the sample supply passage 140; has one end connected to the housing 131 and the other end connected to the automatic supply unit 300.

In addition, the automatic supply unit 300 is connected to a flow path, a valve 310 for adjusting the supply amount of the sample supplied from the flow path; And the valve is connected to the flow path to each of the one or more water collection vessels 200 A supply pipe 330 for injecting a fluid sample; and a nozzle 331 through which a fluid sample is discharged from an end of the supply pipe, and a driving unit 320 for controlling a series of operations of the valve 310 and the supply pipe 330 ); includes.

A plurality of supply pipes and nozzles are provided in accordance with the plurality of partitions,

As the plurality of partitions are composed of two to five, the supply pipe and the nozzle are also composed of two to five, the same as the partition.

In addition, the division part divides the angle of the disk into a plurality of divisions, and the angle forming the division part is Qn (where n is the number of the division part, n=1, 2, 3, 4, 5), and if the angle of the entire division part is added, 360 degrees do.

And it is characterized in that the angles Q1 to Qn forming the partition are the same or different.

In addition, the water collecting container 200 includes an upper surface and a lower surface, and a side surface connecting the upper surface and the lower surface, and a predetermined space is formed therein, and the side surface includes a left surface, a right surface, a rear surface, and a front surface.

In addition, the water collecting container 200 includes an inlet hole 210 formed on the upper surface; and a protrusion 202 protruding along the edge of the inlet hole; and a cover coupled to contact the outer surface of the protrusion to seal the inlet hole. Including, the fluid sample is introduced into the water collecting container through the inlet hole 210, and the liquid sample is introduced into the water collecting container through the part 201; and a concave part 220 respectively provided on two sides formed to face each other. When all of the fluid samples have flowed into the container, the cover part is characterized in that the water collection container is sealed.

In addition, the concave portion 220; is a circular groove having a predetermined depth formed on the side of the water collecting container 200, the first concave part 221 provided on the left side of the water collecting container 200; And a second concave portion 222 provided on the right side of the water collecting container 200.

In addition, the bottom portion having the deepest depth in the first concave portion 221 is in surface contact with the bottom portion having the deepest depth in the second concave portion 222.

In addition, the water collection container 200 is characterized in that it may further include a handle portion 230 formed on the upper surface.

In addition, the protrusion may have an induction part provided in which the height of the outer edge of the upper surface is higher than the height of the inner edge of the upper surface in contact with the inflow hole.

In addition, when one flow path is connected, the driving unit 320 injects a material supplied from the flow path into the water collection container 200 through the supply pipe 330.

In addition, the rotation plate 400 is a rotation module 420 that operates to rotate the rotation plate 400 in a clockwise or counterclockwise direction; and a sensor collecting a movement distance and a rotation angle of the rotation plate 400 A unit 430; and a data transmission/reception unit 410 for transmitting and receiving data to and from the driving unit.

The sensor unit stores angle information of the division start point and the division end point for each division before the rotation of the plate starts, and for each division based on the moving distance and rotation angle of the rotation plate 400 When the current position of the nozzle 331 is determined and the position of the nozzle 331 is aligned with the inlet hole 210 of the water collection container disposed at the compartment end point, Transmits a request signal to stop supplying the sample.

In addition, the driving unit 320 injects a fluid sample supplied from the sample supply passage into one or more water collection containers 200, but when a sample supply stop request signal is received from the data transmission/reception unit 410, the valve 310 Stops the supply of the fluid sample from the sample supply flow path 140 connected to the nozzle 331 disposed at the end of the corresponding section.

In addition, the rotating plate 400 includes one or more mounting grooves 440 into which the lower portion of the water collecting container 200 is inserted, but the mounting groove 440 is a water collecting container mounted on the rotating plate 400 ( 200) is prevented.

In addition, the separation distance between the plurality of watering containers 200 provided on the rotating plate 400 is the same, but the drive unit 320 is the supply pipe 330 by the rotation of the rotating plate 400 When aligned on a vertical line with the inlet hole 210 of 200, a fluid sample is injected into the collection container.

Features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings.

Prior to this, terms or words used in the present specification and claims should not be interpreted in a conventional and dictionary meaning, and the inventor may appropriately define the concept of terms in order to describe his own invention in the best way. It should be interpreted as a meaning and concept consistent with the technical idea of the present invention based on the principle that there is.

As described above, according to the present invention, there is an effect of automating collection and storage of at least one type of fluid sample.

1 is a side view showing a schematic configuration of the present invention.
Figure 2 shows a state looking down from the top of the sample collection device of the present invention.
Figure 3 shows in detail the sample collection unit of the present invention.
Figure 4 shows in detail the configuration of the automatic supply unit and the rotating plate of the present invention.
Figure 5 shows in detail the water collection container of the present invention.
Figure 6 shows a state in which three partitions of the water collection container of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. In this process, the thickness of the lines or the size of components shown in the drawings may be exaggerated for clarity and convenience of description.

In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of users or operators. Therefore, definitions of these terms should be made based on the contents throughout the present specification.

In addition, the following examples are not intended to limit the scope of the present invention, but are merely exemplary matters of the elements presented in the claims of the present invention, and are included in the technical idea throughout the specification of the present invention and the constitution of the claims. Embodiments including elements that can be substituted as equivalents in elements may be included in the scope of the present invention.

1 is a side view showing a schematic configuration of the present invention, and FIG. 2 is a view showing a sample collecting device of the present invention viewed from above.

1 and 2, the present invention relates to one or more sample collection units 100 for each of at least one type of fluid sample; and one or more collection containers for storing fluid samples collected from the sample collection unit 100. (200); And at least one automatic supply unit 300 for each of the fluid samples collected from the sample collection unit 100 to flow into the water collection container 200; And the shape of a circular plate on which the at least one water collection container 200 is mounted Including, but separating the compartment with respect to the space on the upper surface of the rotating plate, one or more water collection containers are located in each compartment, and different fluid samples for each compartment are stored in the collection container. .

In addition, as the automatic supply units are provided in each of the compartments, different fluid samples are introduced into each compartment, and the compartment includes a plurality of compartments.

In the above, the rotating plate 400 separates partitions with respect to the space on the upper surface of the rotating plate, and at least one water collection container is located in each of the partitions, and different fluid samples are stored in the collection container for each partition, and the As each of the compartments is provided with an automatic supply unit, different fluid samples are introduced into each compartment, and the compartment includes a plurality of compartments.

To explain this in more detail, in the present invention, the plurality of partitions may be composed of two to five.

In addition, the division part divides the angle of the disk into a plurality of divisions, and the angle forming the division part is Qn (where n is the number of the division part, n=1, 2, 3, 4, 5), and if the angle of the entire division part is added, 360 degrees do.

And it is characterized in that the angles Q1 to Qn forming the partition are the same or different.

In addition, the rotating plate 400 is rotated clockwise or counterclockwise with respect to a central rotation axis, but at least one water collecting container mounted on the rotating plate 400 according to the rotation of the rotating plate 400 ( 200) is connected to the automatic supply unit 300.

Attached Figure 3 shows in detail the sample collection unit of the present invention.

Referring to FIG. 3, the sample collection unit 100 includes a circulation pipe 110 through which a fluid is circulated; and a circulation pump 120 that is connected to the circulation pipe 110 to induce circulation of the fluid; and the circulation pipe ( 110) a mini-chamber 130 provided to be connected in the middle; including, but the fluid circulated in the circulation pipe 110 is continuously supplied and discharged to the mini-chamber 130.

In addition, the mini-chamber 130 has a structure in which the internal space is sealed, and a housing 131 in which the fluid circulated in the circulation pipe 110 is filled in the internal space; and a fluid filled in the housing 131 Including, the housing 131 is a sample supply passage 140 provided to collect the fluid filled in the housing; characterized in that it is connected to.

In addition, the sample supply passage 140; has one end connected to the housing 131 and the other end connected to the automatic supply unit 300.

Figure 4 shows the configuration of the automatic supply and the rotating plate of the present invention in detail.

Referring to FIG. 4, the automatic supply unit 300 is a valve 310 connected to a flow path to control a supply amount of a sample supplied from the flow path; and the at least one water collecting container 200 connected to the flow path by the valve. ) A supply pipe 330 for injecting a fluid sample into each; and a nozzle 331 through which a fluid sample is discharged from an end of the supply pipe, and a series of operations of the valve 310 and the supply pipe 330 Includes; driving unit 320.

In addition, the rotation plate 400 is a rotation module 420 that operates to rotate the rotation plate 400 in a clockwise or counterclockwise direction; and a sensor collecting a movement distance and a rotation angle of the rotation plate 400 A unit 430; and a data transmission/reception unit 410 for transmitting/receiving data to and from the driving unit.

In addition, the rotating plate 400 may further include one or more mounting grooves 440 into which the lower portion of the water collecting container 200 is inserted, but the mounting groove 440 is mounted on the rotating plate 400. It prevents the separation of the water collection container 200.

To explain this in more detail, a plurality of supply pipes and nozzles are provided in accordance with the plurality of partitions as shown in FIG. 2.

In addition, as the plurality of partitions are composed of two to five, the supply pipe and the nozzle are also composed of two to five, the same as the partition.

Attached Figure 5 shows in detail the water collection container of the present invention.

Referring to FIG. 5, the water collection container 200 includes an upper surface and a lower surface, and a side surface connecting the upper surface and the lower surface, and a predetermined space is formed therein, and the side surface includes a left surface, a right surface, a rear surface, and a front surface.

At this time, the sizes of the front side and the rear side of the water collection container may be formed differently.

In addition, the collection container may be formed such that the front side or the rear side has a predetermined bend.

In addition, the water collecting container 200 includes an inlet hole 210 formed on the upper surface; and a protrusion 202 protruding along the edge of the inlet hole; and a cover coupled to contact the outer surface of the protrusion to seal the inlet hole. Including, the fluid sample is introduced into the water collecting container through the inlet hole 210, and the liquid sample is introduced into the water collecting container through the part 201; and a concave part 220 respectively provided on two sides formed to face each other. When all of the fluid samples have flowed into the container, the cover part is characterized in that the water collection container is sealed.

In addition, the concave portion 220; is a circular groove having a predetermined depth formed on the side of the water collecting container 200, the first concave part 221 provided on the left side of the water collecting container 200; And a second concave portion 222 provided on the right side of the water collecting container 200.

In addition, the bottom portion having the deepest depth in the first concave portion 221 is in surface contact with the bottom portion having the deepest depth in the second concave portion 222.

In the above, the concave portion 220; includes a bottom portion having the deepest depth; and an open circular top surface disposed in a direction opposite to the bottom portion; but the area of the bottom portion may be formed equal to or different from the area of the top surface.

In addition, the shape of the upper surface of the concave portion may have various shapes such as polygonal as well as circular shape.

In addition, the water collection container 200 is characterized in that it may further include a handle portion 230 formed on the upper surface.

In addition, the protrusion may have an induction part provided in which the height of the outer edge of the upper surface is higher than the height of the inner edge of the upper surface in contact with the inflow hole.

In addition, when one flow path is connected, the driving unit 320 injects the material supplied from the flow path into the water collection container 200 through the supply pipe 330.

Referring to FIG. 2 to explain this in more detail, the sensor unit stores angle information of a division start point and angle information of a division end point for each division before the rotation of the plate starts, and the rotation plate 400 ), the current position of the nozzle 331 for each division is determined based on the movement distance and rotation angle of), and when the position of the nozzle 331 is aligned with the inlet hole 210 of the water collection container disposed at the division end point, the It transmits a request signal to stop supplying the sample of the exposure disposed at the end of the division to the driving unit 320.

In addition, the driving unit 320 injects a fluid sample supplied from the sample supply passage into one or more water collection containers 200, but when a sample supply stop request signal is received from the data transmission/reception unit 410, the valve 310 Stops the supply of the fluid sample from the sample supply flow path 140 connected to the nozzle 331 disposed at the end of the corresponding section.

FIG. 6 shows a state in which three compartments of the water collection container of the present invention are provided.

FIG. 6(a) shows a case where the angles of each division are the same when there are three divisions according to the first embodiment of the present invention, and FIG. 6(b) shows a case in which the second embodiment of the present invention When there are three divisions, the angle of each division is different.

In addition, the separation distance between the plurality of water collection containers 200 provided on the rotating plate 400 is identical.

In addition, when the supply pipe 330 is aligned on a vertical line with the inlet hole 210 of the water collecting container 200 by the rotation of the rotating plate 400, the driving unit 320 transfers the fluid sample to the collecting container. Inject.

Although the present invention has been described in detail through specific examples, this is for describing the present invention in detail, and the present invention is not limited thereto, and within the technical idea of the present invention, by those of ordinary skill in the art. It is clear that modifications or improvements are possible.

All simple modifications to changes of the present invention belong to the scope of the present invention, and the specific scope of protection of the present invention will be made clear by the appended claims.

100 Sample collection unit 110 Circulation pipe
120 circulation pump 130 mini chamber
131 Housing 132 Water level measuring section
140 Sample supply flow path 200 Collection vessel
201 Cover 202 Protrusion
210 Inlet hole 220 Recess
221 First recess 222 Second recess
230 Handle part 300 Automatic supply part
310 valve 320 drive
330 supply pipe 331 nozzle
400 rotating plate 410 data transmission/reception unit
420 rotation module 430 sensor unit
440 mounting groove

Claims (12)

One or more sample collection units 100 for collecting at least one or more fluid samples, respectively; And
At least one water sampling container 200 for storing the fluid sample collected by the sample collection unit 100; And
At least one automatic supply unit 300 for each of the fluid samples collected from the sample collection unit 100 to flow into the water collection container 200; And
Including a circular plate-shaped rotating plate 400 on which one or more water collecting containers 200 are mounted; but, partitions are separated with respect to the space on the upper surface of the rotating plate, and at least one water collecting container is located in each of the partitions, and the partition Different fluid samples are stored in the collection container and
In addition, as the automatic supply units are provided in each of the compartments, different fluid samples are introduced into each compartment, and the compartment includes a plurality of compartments. The method of claim 1
The rotating plate 400 separates partitions with respect to the space on the upper surface of the rotating plate, and at least one water collection container is located in each of the partitions, and different fluid samples for each partition are stored in the collection container.
In addition, as the automatic supply units are provided in each of the compartments, different fluid samples are introduced into each compartment, and the compartment includes a plurality of compartments. According to claim 2
The rotating plate 400 rotates clockwise or counterclockwise with respect to a central rotation axis, but at least one water collecting container 200 mounted on the rotating plate 400 according to the rotation of the rotating plate 400 Automatic water collection device, characterized in that connected to the automatic supply unit (300). The method of claim 3
The sample collection unit 100 is
Circulation pipe 110 through which fluid is circulated; And
A circulation pump 120 that is connected to the circulation pipe 110 to induce circulation of the fluid; and
Including; a mini-chamber 130 provided to be connected to the middle of the circulation pipe 110,
Automatic water collection device, characterized in that the fluid circulated in the circulation pipe (110) is continuously supplied and discharged to the mini-chamber (130). According to claim 4
The mini chamber 130 is
A housing 131 in which the fluid circulated in the circulation pipe 110 is filled in the inner space while having a closed structure in the inner space; And
Including; a water level measuring unit 132 for measuring the level of the fluid filled in the housing 131,
The housing 131 is a sample supply flow path 140 provided to collect the fluid filled in the housing; an automatic water collection device, characterized in that connected to. The method of claim 5
The sample supply passage 140; has one end connected to the housing 131
Automatic watering device, characterized in that the other end is connected to the automatic supply unit (300). According to claim 6
The automatic supply unit 300 is
A valve 310 connected to a flow path to control an amount of a sample supplied from the flow path; and
A supply pipe 330 connected to the flow path by the valve to inject a fluid sample into each of the one or more water collection containers 200; And a nozzle 331 through which a fluid sample is discharged from an end of the supply pipe.
Including; a driving unit 320 for controlling a series of operations of the valve 310 and the supply pipe 330,
A plurality of supply pipes and nozzles are provided according to the plurality of partitions,
As the plurality of partitions are composed of two to five, the supply pipe and the nozzle is also composed of two to five, the same as the partition, automatic water collection device. According to claim 7
The division part divides the angle of the disk into a plurality of divisions, and the angle constituting the division part is Qn (where n is the number of the division part, n=1, 2, 3, 4, 5), and when the angle of the entire division part is added, it becomes 360 degrees. Automatic watering device, characterized in that. According to claim 8
An automatic watering device, characterized in that the angles Q1 to Qn forming the partition are the same or different. The method of claim 9
The water collection container 200 consists of an upper surface and a lower surface, and a side surface connecting the upper surface and the lower surface, and a predetermined space is formed inside, and the side surface includes a left side and a right side, a rear side, and a front side. Device. The method of claim 10
The water collection container 200 is
Inlet hole 210 formed on the upper surface; And
A protrusion 202 protruding along the edge of the inlet hole; And
A cover part 201 that is coupled to abut the outer surface of the protrusion to seal the inlet hole; And
Including; recesses 220 provided respectively on two sides formed to face each other,
The fluid sample is introduced into the water collection container through the inlet hole 210, and when all the fluid samples have flowed into the water collection container, the cover part seals the water collection container. The method of claim 11
The concave part 220;
It is a circular groove having a predetermined depth formed on the side of the water collecting container 200
A first concave portion 221 provided on the left side of the water collecting container 200; And
And a second concave portion (222) provided on the right side of the water collecting container (200).

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