阅读说明：本技术 基于水中贾第鞭毛虫、隐孢子虫数字pcr定量检测技术的水样采集装置及采集方法 (Water sample collection device and collection method based on digital PCR quantitative detection technology of giardia and cryptosporidium in water ) 是由 段效辉 李金庆 王颖 杨柏 曲志勇 徐娟 王旭萍 王春雪 姜胜男 史青 曹鹏 于 2021-07-29 设计创作，主要内容包括：本发明公开了基于水中贾第鞭毛虫、隐孢子虫数字PCR定量检测技术的水样采集装置及采集方法,包括浮力板,浮力板连接有水箱,水箱两侧开设有箱板轨道,箱板轨道内滑动连接有封板,封板连接有驱动机构,水箱上端通过进气管连通有进气机构；水箱下方设置有与浮力板相连的固定台,固定台上放置有收集筒,水箱底端与收集筒可拆卸连通,收集筒上下两端分别设置有进水口和出水口；收集筒内滑动连接有芯轴,芯轴底端通过过滤弹簧与收集筒底端相连,芯轴两端固定连接有活动密封片,活动密封片之间设置有与收集筒内壁相连的富集滤芯。本发明可实现贾第鞭毛虫、隐孢子虫定点定量取样工作,且可同时进行多个取样点的取样工作,操作方便,经济实用。(The invention discloses a water sample collecting device and a water sample collecting method based on a giardia and cryptosporidium digital PCR quantitative detection technology in water, wherein the water sample collecting device comprises a buoyancy plate, the buoyancy plate is connected with a water tank, box plate rails are arranged on two sides of the water tank, a sealing plate is slidably connected in the box plate rails and is connected with a driving mechanism, and the upper end of the water tank is communicated with an air inlet mechanism through an air inlet pipe; a fixed platform connected with the buoyancy plate is arranged below the water tank, a collecting cylinder is placed on the fixed platform, the bottom end of the water tank is detachably communicated with the collecting cylinder, and a water inlet and a water outlet are respectively formed in the upper end and the lower end of the collecting cylinder; sliding connection has the dabber in the surge drum, and the dabber bottom links to each other with the surge drum bottom through filtering spring, and dabber both ends fixedly connected with activity gasket is provided with the enrichment filter core that links to each other with the surge drum inner wall between the activity gasket. The invention can realize the fixed-point quantitative sampling work of giardia and cryptosporidium, can simultaneously carry out the sampling work of a plurality of sampling points, and has convenient operation, economy and practicability.)

1. A water sample collecting device based on a digital PCR quantitative detection technology for giardia and cryptosporidium in water comprises a buoyancy plate (7), and is characterized in that the buoyancy plate (7) is connected with a water tank (4), tank plate rails (6) are arranged on two sides of the water tank (4), a sealing plate (9) is slidably connected in the tank plate rails (6), the sealing plate (9) is connected with a driving mechanism, and the upper end of the water tank (4) is communicated with an air inlet mechanism through an air inlet pipe; when the closing plate (9) moves into the box plate track (6), the water tank (4) forms a closed space; a fixed platform (2) connected with the buoyancy plate (7) is arranged below the water tank (4), a collecting barrel (31) is placed on the fixed platform (2), the bottom end of the water tank (4) is detachably communicated with the collecting barrel (31), and the upper end and the lower end of the collecting barrel (31) are respectively provided with a water inlet and a water outlet; a mandrel (34) is connected in the collecting cylinder (31) in a sliding manner, the bottom end of the mandrel (34) is connected with the bottom end of the collecting cylinder (31) through a filtering spring (37), movable sealing sheets (33) are fixedly connected to two ends of the mandrel (34), an enrichment filter element (35) connected with the inner wall of the collecting cylinder (31) is arranged between the movable sealing sheets (33), and the mandrel (34) penetrates through the enrichment filter element (35) and is connected with the enrichment filter element (35) in a sliding manner; in the initial state, the filter spring (37) is in a compressed state, so that a closed space is formed between the two movable sealing sheets (33).

2. The water sample collection device based on the Giardia and Cryptosporidium digital PCR quantitative detection technology in water is characterized in that at least two lifting rods (5) are slidably connected to the buoyancy plate (7), an air cylinder (8) is connected to the upper end of at least one lifting rod (5), the air cylinder (8) is fixedly connected with the buoyancy plate (7), and the lower end of the lifting rod (5) is connected with the fixed platform (2).

3. The water sample collection device based on the Giardia and Cryptosporidium digital PCR quantitative detection technology in water is characterized in that the fixed platform (2) is rotatably connected with a driving gear (22) and at least two driven gears (27), the driven gears (27) and the driving gear (22) are meshed and sleeved with a chain (23), and the driven gears (27) are coaxially connected with a rotating wheel (24); the collecting vessel be provided with a plurality of and all with fixed station (2) sliding connection, at least two runner (24) eccentric connection has poker rod (26), poker rod (26) include a plurality of with collecting vessel (31) matched with stir branch, stir branch with collecting vessel (31) contact.

4. The water sample collection device based on the Giardia and Cryptosporidium digital PCR quantitative detection technology in water is characterized in that the driving gear (22) is coaxially connected with a transmission rod (18) which is rotatably connected with the fixed platform (2), the buoyancy plate (7) is rotatably connected with a transfer rod (163), the bottom end of the transfer rod (163) is connected with a cross joint (162), and the cross joint (162) is sleeved on the transmission rod (18) and is in sliding connection with the transmission rod (18).

5. The water sample collection device based on the Giardia and Cryptosporidium digital PCR quantitative detection technology in water is characterized in that a conical positioning ring (32) is fixedly connected to the upper end of the collection cylinder (31), a sampling slide way (177) is arranged on the buoyancy plate (7), the sampling slide way (177) is arranged above one of the collection cylinders (31), and an adapter rod (174) is arranged in the sampling slide way (177) in a sliding manner; adapter rod (174) bottom fixedly connected with sample ring (175), set up in sample ring (175) in the recess, sliding connection has in the recess with movable block (176) of toper holding ring (32) looks adaptation, movable block (176) through sample spring (172) with the recess inner wall of sample ring (175) links to each other.

6. The water sample collection device based on the Giardia and Cryptosporidium digital PCR quantitative detection technology in water is characterized in that the driving mechanism comprises a retractable wheel (13) rotatably connected with the buoyancy plate (7), a steel wire rope (11) is wound on the retractable wheel (13), and the steel wire rope (11) is connected with the upper end of the sealing plate (9) through a steering wheel (10).

7. The water sample collecting device based on the Giardia and Cryptosporidium digital PCR quantitative detection technology in water is characterized in that a filter screen (41) connected with the inner wall of the water tank (4) is arranged between the box plate rails (6), the upper ends of the box plate rails (6) extend to the outer side of the water tank (4) and are fixedly connected with the bottom ends of the buoyancy plates (7); the bottom of water tank (4) is connected with counter weight seat (1) through first wire rope, fixed station (2) are seted up and are supplied line hole (27) are crossed to first wire rope passes.

8. A method for collecting water samples by using the digital PCR quantitative detection technology of Giardia lamblia and Cryptosporidium in water as claimed in any one of claims 1-7, comprising the following steps:

s1, placing the water tank (4) in water, wherein the buoyancy plate (7) floats on the water surface, and driving the sealing plate (9) to slide along the tank plate rail (6) through the driving mechanism during collection so as to form a closed space in the water tank (4);

s2: then controlling the air inlet mechanism to work, conveying gas into the water tank (4) through the air inlet pipe at intervals of unit time, driving water in the water tank (4) to flow towards the collecting cylinder (31) along with the gas, further driving the movable sealing sheet (33) to move downwards, further driving the core shaft (34) to move downwards, and compressing the filtering spring (37) at the moment so as to open a water inlet and a water outlet of the collecting cylinder (31);

s3: when the primary conveying work is carried out, the gas drives water in the water tank (4) to flow into the collecting cylinder (31) through the water inlet of the collecting cylinder (31) and then flow out through the water outlet of the collecting cylinder (31), in the process, the enrichment filter element (35) finishes the collecting work of giardia and cryptosporidium, and then the filter spring (37) resets, so that a closed space is formed between the two movable sealing sheets (33);

s4: with the intermittent delivery of gas, step S3 is repeated until the water in the tank (4) flows out through the collection cylinder (31), enriching the filter element (35) to complete the collection of giardia and cryptosporidium from the regional water supply.

9. The collection method of the water sample collection device based on the digital PCR quantitative detection technology for giardia and cryptosporidium in water is characterized in that after the collection operation is completed, the cylinder (8) drives the fixed platform (2) to move downwards through the lifting rod (5) and then drives the middle rotating rod (163) to rotate, the middle rotating rod (163) drives the transmission rod (18) to rotate through the cross joint (162), the transmission rod (18) drives the driving gear (22) to rotate, the driving gear (22) drives the rotating wheel (24) to rotate through the chain (23), and the rotating wheel (24) further drives the poking rod (26) to move, so that the collection cylinder (31) moves to the outer side of the water tank (4).

10. The collection method of the water sample collection device based on the Giardia lamblia and Cryptosporidium digital PCR quantitative detection technology in water is characterized in that the adapter rod (174) is placed right above the collection cylinder (31) after collection is completed, then the adapter rod (174) is driven to move downwards, the movable block (176) is matched with the conical positioning ring (32), the sampling spring (172) is compressed at the moment, the sampling ring (175) completes the clamping work of the collection cylinder (31), and then the adapter rod (174) slides in the sampling slide way (177), so that the taking work of the collection cylinder (31) is completed, and the collection work of a new area water source is facilitated.

Technical Field

The invention relates to the technical field of water quality monitoring, in particular to a water sample collecting device and a water sample collecting method based on a Giardia and Cryptosporidium digital PCR quantitative detection technology in water.

Background

Water is necessary for the physiological functions of human bodies, and is the foundation for human survival and social and economic development. The polluted drinking water can cause diseases by harming health, and the supply of qualified domestic drinking water plays an important role in preventing and controlling the diseases.

Giardia (Giardia spp.) and Cryptosporidium (Cryptosporidium spp.) are called as "two worms" for short, are two kinds of pathogenic protozoan parasites, widely spread and prevalent around the world, and the two-worm pollution in drinking water threatens the safety of drinking water for life of people. In recent years, with the increasing demand for quality of drinking water at home and abroad, the research on two insects in drinking water is increasingly paid attention.

To date, most laboratories are often capable of only 104 projects, both cryptosporidium and giardia. The reason is that the collection work of the water samples of cryptosporidium parvum and giardia lamblia is tedious, time-consuming and labor-consuming, the manual labor is heavy, and the quality of the sampling process can not be guaranteed. The original methods are two, one method needs to collect 100 liters (200 jin) of water source water at each water source sampling point, carry the water source water back to a laboratory for concentration and enrichment, the time consumption is 3-4 hours in each 100 liters of water enrichment process, daily regular detection needs to monitor a plurality of sampling points, the workload is very large, and the method is unrealistic; another method is that 100 liters of water can be treated by sampling and enriching on site, multiple persons are needed to cooperate at the same time, a specially-assigned person is needed to check the water meter to prevent the water channel from falling off and breaking, the water channel is often still prevented from being too defeat, the specially-assigned person needs to support the filter to keep the filter vertical, the filter is kept in the state for hours, the work is difficult, the time and the labor are wasted, and the sampling quality is difficult to ensure.

Disclosure of Invention

In order to solve the problems in the prior art, a water sample collecting device and a water sample collecting method based on a Giardia and Cryptosporidium digital PCR quantitative detection technology in water are provided.

The technical scheme adopted by the invention for solving the technical problems is as follows:

the invention provides a water sample collecting device based on a digital PCR quantitative detection technology for giardia and cryptosporidium in water, which comprises a buoyancy plate, wherein the buoyancy plate is connected with a water tank, tank plate rails are arranged on two sides of the water tank, a sealing plate is connected in the tank plate rails in a sliding manner, the sealing plate is connected with a driving mechanism, and the upper end of the water tank is communicated with an air inlet mechanism through an air inlet pipe; when the closing plate moves into the box plate track, the water tank forms a closed space; a fixed platform connected with the buoyancy plate is arranged below the water tank, a collecting barrel is placed on the fixed platform, the bottom end of the water tank is detachably communicated with the collecting barrel, and a water inlet and a water outlet are respectively formed in the upper end and the lower end of the collecting barrel; a mandrel is connected in the collecting cylinder in a sliding manner, the bottom end of the mandrel is connected with the bottom end of the collecting cylinder through a filtering spring, two ends of the mandrel are fixedly connected with movable sealing sheets, an enrichment filter element connected with the inner wall of the collecting cylinder is arranged between the movable sealing sheets, and the mandrel penetrates through the enrichment filter element and is connected with the enrichment filter element in a sliding manner; in the initial state, the filter spring is in a compressed state, so that a closed space is formed between the two movable sealing sheets.

Preferably, the buoyancy plate is connected with at least two lifting rods in a sliding mode, the upper end of at least one lifting rod is connected with an air cylinder, the air cylinder is fixedly connected with the buoyancy plate, and the lower end of the lifting rod is connected with the fixed platform.

Preferably, the fixed table is rotatably connected with a driving gear and at least two driven gears, the driven gears and the driving gear are sleeved with chains in a meshing manner, and the driven gears are coaxially connected with rotating wheels; the collecting cylinder is provided with a plurality of and all with fixed station sliding connection, at least two runner eccentric connections has the poker rod, the poker rod include a plurality of with collecting cylinder matched with stir branch, stir branch with the collecting cylinder contacts.

Preferably, the driving gear is coaxially connected with a transmission rod rotatably connected with the fixed platform, the buoyancy plate is rotatably connected with a transfer rod, the bottom end of the transfer rod is connected with a cross joint, and the cross joint is sleeved on the transmission rod and is in sliding connection with the transmission rod.

Preferably, the upper end of the collecting cylinder is fixedly connected with a conical positioning ring, the buoyancy plate is provided with a sampling slide way, the sampling slide way is arranged above one of the collecting cylinders, and an adapter rod is arranged in the sampling slide way in a sliding manner; the utility model discloses a take out the sample ring, including adapter rod, sampling ring, recess, sliding connection have with the movable block of toper holding ring looks adaptation in the recess, the movable block pass through the sample spring with the recess inner wall of sampling ring links to each other.

Preferably, the driving mechanism comprises a retractable wheel which is rotatably connected with the buoyancy plate, a steel wire rope is wound on the retractable wheel, and the steel wire rope is connected with the upper end of the sealing plate through a steering wheel.

Preferably, a filter screen connected with the inner wall of the water tank is arranged between the box plate rails, and the upper ends of the box plate rails extend to the outer side of the water tank and are fixedly connected with the bottom ends of the buoyancy plates; the bottom of water tank is connected with the counter weight seat through first wire rope, the fixed station is seted up and is supplied first wire rope passes the line hole.

The invention also provides a water sample collecting device collecting method based on the digital PCR quantitative detection technology of the giardia lamblia and the cryptosporidium in the water, which comprises the following steps:

s1, placing the water tank in water, wherein the buoyancy plate floats on the water surface, and when collecting, the sealing plate is driven by the driving mechanism to slide along the plate track, so that a closed space is formed inside the water tank;

s2: then controlling the air inlet mechanism to work, conveying gas into the water tank once through the air inlet pipe at intervals of unit time, driving water in the water tank to flow towards the collecting cylinder along with the gas, further driving the movable sealing sheet to move downwards, so as to drive the core shaft to move downwards, and compressing the filtering spring at the moment, so as to open a water inlet and a water outlet of the collecting cylinder;

s3: during one-time conveying work, the gas drives water in the water tank to flow into the collecting cylinder through the water inlet of the collecting cylinder and then flow out of the water outlet of the collecting cylinder, in the process, the enrichment filter element finishes collecting giardia and cryptosporidium, and then the filter spring resets, so that a closed space is formed between the two movable sealing sheets;

s4: with the intermittent delivery of the gas, step S3 is repeated until the water in the water tank flows out through the collecting cylinder, and the filter element is enriched so as to complete the collecting work of giardia and cryptosporidium in the water source of the area.

Preferably, after the collection work is completed, the cylinder drives the fixed station to move downwards through the lifting rod, then the transfer rod is driven to rotate, the transfer rod drives the transmission rod to rotate through the cross joint, the transmission rod drives the driving gear to rotate, the driving gear drives the rotating wheel to rotate through the chain, and the rotating wheel further drives the poking rod to move, so that the collecting cylinder moves to the outer side of the water tank.

Preferably, place the switching pole directly over the collecting vessel after the collection is accomplished, then drive the switching pole and remove downwards, the movable block cooperatees with the toper holding ring, the compression of sample spring this moment, thereby the tight work of clamp to the collecting vessel is accomplished to the sample ring, then slides the switching pole from the slide that takes a sample to accomplish the work of taking of collecting vessel, the collection work at the new regional water source of being convenient for.

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

1. the water tank is provided with the collecting cylinder, gas is conveyed into the water tank through the gas inlet mechanism, the gas drives water to flow out through the collecting cylinder, in the process, the enrichment filter element finishes collecting work on giardia and cryptosporidium, fixed gas is conveyed into the water tank at intervals of unit time, and the filter spring drives the movable sealing sheet to reset after each time of gas conveying is finished, so that the water in the water tank finishes the enrichment work, the workload is effectively reduced, the phenomenon that 100L of water is lifted each time to return in the traditional detection process is avoided, the working strength is reduced, the operation is simpler, the time is effectively saved, and the detection efficiency can be improved.

2. The invention is also provided with a transfer lever which drives the driving gear to rotate and further drives the driven gear to rotate, so as to drive the eccentrically connected poke rod to rotate, and the driven gear can drive the collecting cylinder to advance by one unit length every time the driven gear rotates by one circle, so as to drive a new collecting cylinder to carry out collection work, thus realizing the installation and position supplementing work of the collecting cylinder, facilitating the sample collection work at different positions and realizing multi-point sampling.

3. According to the invention, the adapter rod can be placed above the collection cylinder after collection, when the adapter rod moves downwards, the conical surface of the movable block is matched with the conical positioning ring, the sampling spring is compressed, so that the collection cylinder after collection is clamped by the sampling ring, the collection cylinder is taken out, and when the sampling operation of one sampling point is completed, the collection cylinder is taken out, so that when a new round of collection operation is prevented, water flow can flow into the collection cylinder, the collection quality is poor, the sampling efficiency is better, the sampling quality is better, the structure is reasonable, and the sampling device is economical and practical.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

FIG. 1 is an overall front view of the present invention;

FIG. 2 is an overall side view of the present invention;

FIG. 3 is a front view of the cartridge structure of FIG. 1;

FIG. 4 is a top view of the collection cartridge of FIG. 1;

FIG. 5 is a bottom view of the cartridge structure of FIG. 1;

FIG. 6 is a front view of the connecting rod structure of FIG. 2;

FIG. 7 is a schematic view of the sample ring portion of FIG. 6;

FIG. 8 is a sectional view of the ring portion of the sample of FIG. 6;

FIG. 9 is a front view of the transfer lever structure of FIG. 2;

FIG. 10 is a sectional view of the fixed station structure of FIG. 1;

FIG. 11 is a top view of the mounting plate structure of FIG. 1;

FIG. 12 is a schematic view of the tap lever of FIG. 10;

FIG. 13 is a cross-sectional view of the buoyancy plate structure of FIG. 1;

fig. 14 is a schematic view of the structure in the direction K in fig. 1.

Description of reference numerals:

1, a counterweight seat; 4, a water tank; 41, a filter screen; 5, a lifting rod; 6 boxboard track; 7, a buoyancy plate; 8 air cylinders; 9, closing a plate; 10 a steering wheel; 11 a steel wire rope; 12, a guide sleeve; 13, retracting and releasing wheels; 14, retracting and releasing the handle; 15 positioning a ring; 18 a transmission rod;

2, fixing a table; 21 an annular guide block; 22 a drive gear; 23, chains; 24 rotating wheels; 25 a driven gear; 26 a poke rod; 27 a wire through hole;

31 a collection canister; a 32-cone shaped locating ring; 33 movable sealing sheets; 34 a mandrel; 35 enriching the filter element; 36, guiding a fixed sleeve; 37 a filter spring; 38 a guide post;

161 hand wheel; 162 a cross joint; 163 a turn bar; 164 rotating the positioning hole;

171 a handle; 172 sampling spring; 173 linear bearings; 174 an adapter rod; 175 sampling circle; 176 a movable block; 177 sampling slide.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative only for the purpose of explaining the present invention, and are not to be construed as limiting the present invention.

As shown in fig. 1 to 14, the present embodiment provides a water sample collecting device based on a digital PCR quantitative detection technique for giardia and cryptosporidium in water, which includes a buoyancy plate 7, wherein the buoyancy plate 7 floats on the water surface under the buoyancy action of water.

Buoyancy board 7 sliding connection has two at least lifter 5, and 5 upper ends of at least one lifter are connected with cylinder 8, cylinder 8 and buoyancy board 7 fixed connection, the lower extreme fixedly connected with fixed station 2 of lifter 5. In this example, the lifting rods 5 are provided with 4 lifting rods, and are respectively arranged on four opposite corners of the fixed platform 2, the air cylinders 8 are provided with two lifting rods, and are symmetrically arranged along the diagonal line of the buoyancy plate 7, so that the lifting process of the fixed platform 2 can be smoother, and the whole fixed platform 2 is more stable.

Buoyancy board 7 is connected with water tank 4, and case board track 6 has been seted up to 4 both sides of water tank, and sliding connection has shrouding 9 in case board track 6, and shrouding 9 is connected with actuating mechanism, when shrouding 9 removed in case board track 6, makes water tank 4 form the enclosure space.

Be provided with the filter screen 41 that links to each other with the water tank 4 inner wall between the boxboard track 6, filter screen 41 plays filterable effect to the impurity of aquatic to when making rivers flow through in the water tank 4, impurity can shelter from in the outside of water tank 4. Wherein the filter screen 41 is arranged outside the boxboard track 6.

The upper end of the box plate track 6 extends to the outer side of the water tank 4 and is fixedly connected with the bottom end of the buoyancy plate 7; the bottom of water tank 4 is connected with counter weight seat 1 through first wire rope, and fixed station 2 sets up the line hole 27 that crosses that supplies first wire rope to pass.

The counterweight seat 1 is used for driving the water tank 4 to be in a vertical state in water all the time, and the water tank 4 is prevented from shaking under the action of water flow. And boxboard track 6 is provided with 4 altogether, and sets up four diagonal positions at water tank 4 respectively, and wherein 6 opening part of boxboard track that the symmetry set up are as shown in fig. 1 to make shrouding 9 all the time in boxboard track 6, prevent that shrouding 9 from taking place to rock, and when shrouding 9 slided boxboard track 6 during the below, water tank 4 can form the enclosure space, prevent to carry out the ration sample work, rivers get into in the water tank 4, thereby influence the going on of sample work.

The upper end of the water tank 4 is communicated with an air inlet mechanism through an air inlet pipe, the air inlet mechanism can adopt an air pump in the example for inflating, and when air enters the water tank 4 through the air inlet pipe, the air in the water tank 4 is driven to flow downwards under the action of the air.

Water tank 4 sets up in the top of fixed station 2, has placed collecting vessel 31 on fixed station 2, and the intercommunication can be dismantled with collecting vessel 31 in 4 bottoms of water tank. Wherein the bottom of water tank 4 is the inclined plane to make things convenient for in the water homoenergetic in the water tank 4 gets into the surge drum 31, the junction of water tank 4 and surge drum 31 is provided with holding ring 15, holding ring 15 and water tank 4 fixed connection. The toper holding ring 32 of fixedly connected with in the top of the collecting vessel 31, toper holding ring 32 cooperatees with holding ring 15, and when cylinder 8 drove the fixed station 2 and rises, toper holding ring 32 laminated each other with holding ring 15 to make water tank 4 and collecting vessel 31 be linked together, do benefit to the enrichment work of rivers in the water tank 4.

The upper end and the lower end of the collecting cylinder 31 are respectively provided with a water inlet and a water outlet; a mandrel 34 is connected in the collecting cylinder 31 in a sliding manner, the bottom end of the mandrel 34 is connected with the bottom end of the collecting cylinder 31 through a filtering spring 37, two ends of the mandrel 34 are fixedly connected with movable sealing pieces 33, an enrichment filter element 35 connected with the inner wall of the collecting cylinder 31 is arranged between the movable sealing pieces 33, and the mandrel 34 penetrates through the enrichment filter element 35 and is connected with the enrichment filter element 35 in a sliding manner; in the initial state, the filter spring 37 is in a compressed state, so that a closed space is formed between the two movable sealing sheets 33. The enrichment filter element 35 is detachably connected with the inner wall of the collecting cylinder 31, so that the collection of the enrichment filter element 35 can be replaced after collection and the new placement of the enrichment filter element 35 can be facilitated.

Wherein, the guide post 38 of the fixedly connected with of collecting vessel 31 bottom, set up the recess in the guide post 38, the bottom of filter core 35 slides and sets up in this recess, and this recess plays spacing effect to the removal of filter core 35 on the one hand, and on the other hand prevents that filter core 35 from removing too much distance downwards.

The filtering spring 37 is sleeved in the guide post 38, the upper end of the filtering spring 37 is connected with the guide post 38, the lower end of the filtering spring 37 is connected with the inner wall of the collecting barrel 31, and the filtering spring 37 is used for resetting the filter element 35, so that the filter element 35 is driven to move upwards.

The movable sealing piece 33 is provided with two, and under initial state, the movable sealing piece 33 all with collection section of thick bamboo 31 looks adaptation, the structure of movable sealing piece 33 is as shown in fig. 4, the water inlet and the movable sealing piece 33 looks adaptation of collection section of thick bamboo 31 to when movable sealing piece 33 and collection section of thick bamboo 31 contact, can form the shrouding space between two movable sealing pieces 33, prevent the entering of rivers.

The enrichment filter element 35 adopts a conventional structure, the water outlet of the collecting cylinder 31 is shown in fig. 5, the empty place is the water outlet, when water flows through the water inlet of the collecting cylinder 31 and then flows out from the water outlet, the enrichment filter element 35 is used for collecting giardia and cryptosporidium.

Fixed station 2 is the annular guide block 21 of fixedly connected with still, and two fixed uide bushing 36 of collecting vessel 31 fixedly connected with, wherein annular guide block 21 sets up between fixed uide bushing 36, and fixed uide bushing 36 plays spacing effect through annular guide block 21 to collecting vessel 31 to make collecting vessel 31 can slide along the length direction of fixed station 2 all the time, wherein, guide post 38 and fixed station 2 sliding connection.

The fixed table 2 is rotatably connected with a driving gear 22 and at least two driven gears 27, the driven gears 27 and the driving gear 22 are meshed and sleeved with a chain 23, and the driven gears 27 are coaxially connected with a rotating wheel 24; the collecting cylinder is provided with a plurality of and all with fixed station 2 sliding connection, and at least two runners 24 eccentric connections have poker rod 26.

The poke rod 26 comprises a plurality of poking supporting rods matched with the collecting barrels 31, the poking supporting rods are in contact with the collecting barrels 31, the number of the poking supporting rods is matched with the number of the collecting barrels 31, when the poke rod 26 rotates, all the collecting barrels 31 can be driven to slide along the length direction of the fixed table 2, when the driven gear 27 rotates for every circle, the collecting barrels 31 can be driven to advance by one unit length, and two adjacent poking supporting rods can play a limiting role in the collecting barrels 31.

The driving gear 22 is coaxially connected with a transmission rod 18 which is rotatably connected with the fixed platform 2, the buoyancy plate 7 is rotatably connected with a transfer rod 163, the bottom end of the transfer rod 163 is connected with a cross joint 162, and the cross joint 162 is sleeved on the transmission rod 18 and is in sliding connection with the transmission rod 18.

The upper end fixedly connected with hand wheel 161 of transfer pole 163, hand wheel 161 conveniently drives transfer pole 163 and rotates, and buoyancy plate 7 has seted up and has rotated locating hole 164, and transfer pole 163 sets up in rotating locating hole 164, rotates locating hole 164 and plays spacing effect to transfer pole 163.

The cross joint 162 can slide vertically relative to the transmission rod 18, so that when the air cylinder 8 drives the fixing platform 2 to descend, the transmission rod 18 and the cross joint 162 slide relatively, but the transmission rod 18 and the cross joint 162 are always in a contact state, so that when the middle rotating rod 163 rotates, the transmission rod 18 can be driven to rotate through the cross joint 162.

The buoyancy plate 7 is provided with a sampling slide way 177, the sampling slide way 177 is arranged above one of the collecting cylinders 31, and the adapter rod 174 is arranged in the sampling slide way 177 in a sliding manner; the bottom end of the adapter rod 174 is fixedly connected with a sampling ring 175, a groove is arranged in the sampling ring 175, a movable block 176 matched with the conical positioning ring 32 is connected in the groove in a sliding manner, the movable block 176 is connected with the inner wall of the groove of the sampling ring 175 through a sampling spring 172, and the groove plays a limiting role in the sliding of the movable block 176.

The shape of the sampling chute 177 is as shown in fig. 13, the upper end of the adapter rod 174 is fixedly connected with the handle 171, the adapter rod 174 can slide along the length direction of the sampling chute 171, the bottom end of the sampling chute 171 is provided with the linear bearing 173, the adapter rod 174 can slide into the linear bearing 173, the linear bearing 173 plays a role in facilitating the adapter rod 174 to slide in the vertical direction, the friction force during sliding is reduced, and the adapter rod 174 can only slide in the vertical direction and cannot rotate.

The adapter rod 174 is disposed above the rightmost collecting barrel 3, the inclined surface of the movable block 176 is matched with the conical positioning ring 32, the sampling spring 172 is disposed in the groove of the sampling circular ring 175, one end of the sampling spring 172 is connected with the movable block 176, and the other end of the sampling spring 172 is connected with the sampling circular ring 175, so that when the sampling spring 172 is compressed, the movable block 176 can clamp the collecting barrel 3.

The driving mechanism comprises a retracting wheel 13 which is rotationally connected with the buoyancy plate 7, a steel wire rope 11 is wound on the retracting wheel 13, and the steel wire rope 11 is connected with the upper end of the sealing plate 9 through a steering wheel 10.

The steering wheel 10 is arranged above the buoyancy plate 7, the buoyancy plate 7 is fixedly connected with a connecting rod, the steering wheel 10 is rotatably connected with the connecting rod, the steel wire rope 11 is sleeved on the steering wheel 10 in a sliding mode, and the steering wheel 10 plays a role in guiding the movement of the steel wire rope 11.

The upper end of the buoyancy plate 7 is also fixedly connected with a guide sleeve 12, one side of the retractable wheel 13 is fixedly connected with a retractable handle 14, the retractable handle 14 is convenient for the retractable wheel 13 to rotate, the retractable wheel 13 comprises a locking mechanism, and the locking mechanism is used for locking the retractable wheel 13 and preventing the retractable wheel 13 from freely rotating.

The steel wire rope 11 is arranged in the guide sleeve 12 in a sliding mode, the upper end of the steel wire rope 11 penetrates through the guide sleeve 12 to be divided into two steel wire ropes, and the two steel wire ropes are connected with the two sealing plates 9 respectively.

Digital PCR technology refers to the challenge of absolute quantification of pathogens in environmental samples using qPCR. First, the generation of standard curves is often a cumbersome process, and the lack of reference standard curves can confound the comparison of qPCR results between laboratories. Secondly, the use of qPCR to quantify genetic signatures representing different pathogens in complex environments is quite challenging. Small amounts of PCR inhibitors may delay the threshold cycle (Cq) value, leading to an underestimation of template copy number. The development of the relatively new digital polymerase chain reaction has the potential to overcome the problems associated with absolute quantification of qPCR.

In digital polymerase chain reaction, the sample is diluted and divided into several chambers so that each chamber contains one or zero copies of the sequence of interest prior to PCR amplification. The exact copy number of the target DNA in the sample can be determined by counting the number of positives and negatives. However, even under optimal conditions (adequate distribution of the sample), the possibility of more than one molecule per reaction is always present. There are two types of digital PCR platforms i) chip-based digital PCR, ii) droplet-based digital PCR. Emulsion-in-water based digital micro-droplet pcr (ddpcr) has many advantages over qPCR and does not require external standard curves (Hindson et al, 2011; Pinheiro et al, 2012).

Several studies have reported the use of ddPCR to simultaneously quantify bacteria and viruses in different clinical and environmental samples. But its application in the environment is very limited. Cao et al define the use of digital PCR in water monitoring applications and view it as a molecular method for field applications. The application of ddPCR in the detection of cryptosporidium and giardia has not been widely explored, and the existing information is limited. Yang et al (2014) compared the quantitation of Cryptosporidium targeted at the 18S rRNA and actin genes by ddPCR and qPCR.

Different DNA templates of cryptosporidium are adopted to compare the linearity, sensitivity, precision and cost of the two methods. qPCR and ddPCR show a significant linear relationship as measured by relative standard deviation, and ddPCR accuracy is better than qPCR. ddPCR accuracy decreases with decreasing DNA concentration, while qPCR is unaffected by template concentration. It was also observed that ddPCR was less affected by PCR inhibitors, but the total cost of ddPCR was found to be twice that of qPCR. The authors advocated the use of ddPCR to accurately quantify the serial dilutions required to prepare the qPCR standard curve. Zahedi et al also used ddPCR to quantify the exact copy number of Cryptosporidium in standard dilutions of oocysts used for qPCR.

With the development of modern molecular biology technology, quantitative PCR (qPCR) technology is favored by its features of rapidness, sensitivity, and strong specificity. A large number of documents show that the qPCR technology for detecting the two insects can improve the detection sensitivity and greatly reduce the experimental expense and manpower and material resources; there are still drawbacks of low copy target molecules, relatively poor sensitivity and accuracy in subtle template concentration differences. The digital PCR technology adopts a high-density nano liter flow control chip technology, can detect low to single copy samples, greatly improves the detection sensitivity, and has the advantages of low variation degree and accurate quantification.

On the basis of earlier work, the invention is based on a digital PCR detection method of giardia and cryptosporidium in drinking water, and the quantification in the quantitative detection technology is based on the water volume of 100L formed by the water tank 4.

The invention also provides an acquisition method, and the water sample acquisition device based on the digital PCR quantitative detection technology of the giardia lamblia and the cryptosporidium in the water comprises the following steps:

s1, placing the water tank 4 in water, wherein the buoyancy plate 7 floats on the water surface, and when collecting, the sealing plate 9 is driven by the driving mechanism to slide along the tank plate track 6, so that a closed space is formed inside the water tank 4;

s2: then controlling the air inlet mechanism to work, conveying gas into the water tank 4 through the air inlet pipe at intervals, driving water in the water tank 4 to flow towards the collecting cylinder 31 along with the gas, further driving the movable sealing sheet 33 to move downwards, further driving the core shaft 34 to move downwards, and compressing the filtering spring 37 at the moment so as to open a water inlet and a water outlet of the collecting cylinder 31;

s3: during one-time conveying work, the gas drives water in the water tank 4 to flow into the collecting cylinder 31 through the water inlet of the collecting cylinder 31 and flow out through the water outlet of the collecting cylinder 31, in the process, the enrichment filter element 35 finishes collecting giardia and cryptosporidium, and then the filter spring 37 resets, so that a closed space is formed between the two movable sealing sheets 33;

s4: with the intermittent delivery of gas, step S3 is repeated until the water in tank 4 flows out through collection cylinder 31, enriching cartridge 35 to complete the collection of giardia and cryptosporidium from the regional water supply.

After the collection operation is completed, the cylinder 8 drives the fixing table 2 to move downwards through the lifting rod 5, then drives the middle rotating rod 163 to rotate, the middle rotating rod 163 drives the transmission rod 18 to rotate through the cross joint 162, the transmission rod 18 drives the driving gear 22 to rotate, the driving gear 22 drives the rotating wheel 24 to rotate through the chain 23, and the rotating wheel 24 further drives the poking rod 26 to move, so that the collecting cylinder 31 moves to the outer side of the water tank 4.

Place adapter rod 174 directly over the collection section of thick bamboo 31 after the collection is accomplished, then drive adapter rod 174 downstream, the movable block 176 cooperatees with toper holding ring 32, and sample spring 172 compresses this moment, thereby sample ring 175 accomplishes the tight work of clamp to collection section of thick bamboo 31, then slides adapter rod 174 from the slide 177 that takes a sample to the work of taking of completion collection section of thick bamboo 31, the collection work of the new regional water source of being convenient for.

It should be noted that, during sampling, the filter screen 41 filters water flow to prevent garbage in the water source from entering the water tank 4. The water tank 4 forms a 100L water volume. After the sampling operation of the water source in the area is completed, when a new round of sampling operation is performed, the air cylinder 8 drives the fixing table 2 to ascend by a proper height, so that the collecting cylinder 31 is communicated with the water tank 4.

The method for driving the sealing plate 9 to move by the driving mechanism comprises the steps that the locking mechanism does not limit the rotation of the retractable wheel 13 any more, the retractable handle 14 is rotated to drive the retractable wheel 13 to rotate, and the sealing plate 9 can move into the box plate track 6 of the water tank 4 under the action of the self gravity of the sealing plate 9.

In addition, in the invention, the air inlet mechanism conveys air into the water tank 4 once every unit time interval, the air drives water to flow out through the collecting cylinder 3, and in the process, the enrichment filter element 35 finishes the collecting work of giardia and cryptosporidium. And after the enrichment work is finished, taking out the cryptosporidium and giardia detecting and enriching filter element 35, putting the cryptosporidium and giardia detecting and enriching filter element into a self-sealing bag, sealing the bag opening, marking a sampling point, putting the self-sealing bag into a low-temperature place, and taking the self-sealing bag back to a transfer laboratory to finish the elutriation detection within 72 hours.

Every unit interval is to the in-process of carrying fixed gas in the water tank 4, and after gas transport was accomplished at every turn, the filtering spring 37 all drove movable sealing piece 33 and resets to make the water in the water tank 4 accomplish the enrichment work, effectively reduced work load, avoided when tradition detected, carried 100L water at every turn and got back, reduced working strength, the operation is simpler, has effectively practiced thrift the time, and can improve the efficiency that detects.

The transfer lever 163 drives the driving gear 22 to rotate, and then drives the driven gear 25 to rotate, thereby driving the eccentric connection of the poker rod 26 to rotate, the driven gear 25 rotates the round at every turn, thereby can drive the collecting cylinder 3 to advance a unit length, drive new collecting cylinder 3 and carry out the collection work, realized the installation of collecting cylinder 3, mended the position work, conveniently carry out the sample collection work of different positions, realize the multiple spot sample.

In addition, the adapter rod 174 can be placed above the collecting cylinder 3 after the collection is completed, when the adapter rod 174 moves downwards, the conical surface of the movable block 176 is matched with the conical positioning ring 32, the sampling spring 172 is compressed, and the sampling ring 175 clamps the collecting cylinder 3 after the collection is completed, so that the collecting cylinder 3 is taken out, and when the sampling operation of one sampling point is completed, the collecting cylinder 3 is taken out, so that the situation that water flow possibly flows into the collected collecting cylinder 3 when a new round of collection operation is performed and the collection quality is poor is avoided.

While embodiments of the invention have been shown and described, it will be understood by those of ordinary skill in the art that: various changes, modifications, substitutions and alterations can be made to the embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the claims and their equivalents.