CN210243285U - Water sample collection device for underground water engineering - Google Patents

Abstract

The utility model discloses a groundwater engineering water sample collection system belongs to groundwater reconnaissance equipment technical field, including bearing the installation component, setting up at the collection drive assembly who bears the installation component first half and the location collection part of being connected with the transmission of collection drive assembly, the location collection part includes coupling assembling, linkage subassembly and a plurality of collection subassembly that sets gradually along vertical direction, linkage subassembly and the equal swing joint of all collection subassemblies, coupling assembling runs through all collection subassemblies in proper order and connects all collection subassemblies the shaping, and is a plurality of the collection subassembly can reciprocate, every along vertical direction the collection end of collection subassembly is all vertical upwards. The utility model discloses can gather the sample to the different degree of depth in same secret waters simultaneously, solve prior art, need through the loaded down with trivial details of the repeated collection water sampling many times, reduce the output of manpower and materials.

Description

Water sample collection device for underground water engineering

Technical Field

The utility model belongs to the technical field of groundwater reconnaissance equipment technique and specifically relates to a groundwater engineering water sample collection system is related to.

Background

The geological engineering field is based on the natural science and the earth science as theoretical basis, engineering problems related to geological survey, general survey and exploration of mineral resources, and geological structure and geological background of major engineering are taken as main objects, geology, geophysical and geochemical technologies, mathematical geological methods, remote sensing technologies, testing technologies, computer technologies and the like are taken as means, the pilot engineering field serving national economic construction is served, the method for testing by adopting underground water samples to evaluate the corrosivity of water to concrete structures is important content of engineering geological survey, and the testing items comprise pH value, Mg2+, CL-, SO42-, HCO3-, erosive CO2, NH4+, OH-and the like.

Groundwater collection equipment among the prior art, at the in-process of gathering, can only gather the water sample of a certain position of groundwater, if need gather the water sample of the different degree of depth, just need through the repeated sampling step many times, the sampling process is loaded down with trivial details, and consumes manpower and materials huge.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a groundwater engineering water sample collection system to solve the technical problem among the prior art.

The utility model provides an underground water works water sample collection system, gather the part including bearing the weight of the installation part, setting at the collection driver part who bears the weight of installation part first half and the location of being connected with the transmission of collection driver part, the location is gathered the part and is included coupling assembling, linkage assembly and a plurality of collection subassembly that sets gradually along vertical direction, linkage assembly and the equal swing joint of all collection subassemblies, coupling assembling runs through all collection subassemblies in proper order and connects all collection subassemblies into shape, and is a plurality of collection subassembly can reciprocate, every along vertical direction the collection end of collection subassembly is vertical upwards all.

Further, bear the weight of the installation component including bearing mounting panel, drive mounting panel, two symmetric distributions bearing the weight of the mounting panel top and can carry out the hanging support plate and a plurality of location support columns that are the rectangular structure and distribute bearing the weight of the mounting panel bottom of dismouting operation, the top of drive mounting panel and all location support columns's bottom fixed connection.

Further, every gather the subassembly including gathering locating plate, vertical location cover and horizontal collection portion, horizontal collection portion sets up the top at gathering the locating plate, vertical location cover establish on horizontal collection portion and with the top fixed connection who gathers the locating plate, the both ends of gathering the locating plate top are equipped with the rectangle that supplies the collection end of horizontal collection portion to deposit respectively and lead to the groove, every the rectangle leads to the groove and all runs through along vertical direction and gathers the locating plate.

Further, horizontal collection portion includes two-way drive electric jar, two horizontal drive presss from both sides and two collection graduated flasks, two-way drive electric jar sets up at the top of gathering the locating plate, two horizontal drive presss from both sides and sets up respectively on two output ends of two-way drive electric jar, two collection graduated flask and two horizontal drive press from both sides one-to-one, under inoperative condition, every collection graduated flask all sets up at the logical inslot of rectangle, every the uncovered of collection graduated flask all upwards.

Further, coupling assembling includes four spliced poles that are the distribution of rectangle structure, every the one end of spliced pole and the bottom fixed connection of drive mounting panel, the other end of spliced pole runs through all collection locating plates in proper order along vertical direction, and finally with the collection locating plate fixed connection of bottommost, every the collection locating plate homoenergetic slides on four spliced poles.

Further, the linkage subassembly includes that two symmetries set up all gather the linkage portion of locating plate both sides, every linkage portion includes the connecting plate that a plurality of groups intercrossed set up, every group the connecting plate all can change along vertical direction, all the connecting plate is with the shaping of connecting one side of all collection locating plates.

Further, gather the drive assembly including gathering location electric jar, drive locating plate and two collection reference columns, two it is vertical state to gather the reference column and installs and be close to on the collection locating plate of drive mounting panel, every gather the bottom of reference column all with the top fixed connection of drive mounting panel, the drive locating plate is installed at two tops of gathering the reference column, gather the setting of location electric jar on the drive mounting panel, gather the vertical downward and with the top fixed connection of drive locating plate of output shaft of location electric jar.

Compared with the prior art, the beneficial effects of the utility model reside in that:

firstly, because according to different detection requirements, sampling positions and sampling components in each time are different, because underground water needs to be sampled, the sampling depth is very deep, downlink power needs to be provided through other machines, the sampling device is matched with a lifting hydraulic machine for use, firstly, the top of a bearing mounting part is mounted at the output end of the lifting hydraulic machine, according to the preset sampling depth, all the acquisition assemblies are connected in series through a connecting assembly, then the side parts of all the acquisition assemblies are connected through a linkage assembly, so that the positions of all the acquisition assemblies can be extended and contracted along the vertical direction, then the acquisition driving part drives the acquisition assembly close to the acquisition assembly to move, the positions of all the acquisition assemblies can be controlled, the acquisition depth in the underground water acquisition process can be controlled, and the acquisition and sampling can be simultaneously carried out on different depths of the same underground water area, the problem of among the prior art, need through the loaded down with trivial details of many times repeated collection water sampling, reduced the output of manpower and materials is solved.

Two, because every horizontal collection portion all includes the both-way drive electric jar, two horizontal drive press from both sides and two collection graduated flasks, when the operation of water sample is gathered to needs, can drive two horizontal drive through the both-way drive electric jar and press from both sides and two collection graduated flasks along the outside removal of horizontal direction, then two collection graduated flasks all extend to the outside of whole device, the water sampling of being convenient for, after the water sample is gathered and is accomplished, two horizontal drive of rethread two-way drive electric jar drive press from both sides and two collection graduated flasks along the horizontal direction inside removal, retract to the rectangle that gathers the locating plate and lead to the inslot, when retrieving whole sampling device, just can reduce the lateral contact area of whole device, then can avoid area of contact too big, and cause the damage of equipment.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the technical solutions in the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a schematic perspective view of the present invention;

fig. 2 is a front view of the present invention;

FIG. 3 is a cross-sectional view taken along line A-A of FIG. 2;

FIG. 4 is a schematic view of a partial three-dimensional structure of the present invention;

fig. 5 is an enlarged view at B in fig. 4.

Reference numerals:

the device comprises a bearing mounting component 1, a bearing mounting plate 1a, a driving mounting plate 1b, a hanging support plate 1c, a positioning support column 1d, an acquisition driving component 2, an acquisition positioning electric cylinder 2a, a driving positioning plate 2b, an acquisition positioning column 2c, a positioning acquisition component 3, a connecting component 3a, a connecting column 3a1, a linkage component 3b, an acquisition component 3c, an acquisition positioning plate 3d, a rectangular through groove 3d1, a vertical positioning cover 3e, a transverse acquisition part 3f, a bidirectional driving electric cylinder 3f1, a transverse driving clamp 3f2, an acquisition measuring cup 3f3, a linkage part 3g and a connecting plate 3g1,

Detailed Description

The technical solution of the present invention will be described clearly and completely with reference to the accompanying drawings, and obviously, the described embodiments are some, but not all embodiments of the present invention.

The components of the embodiments of the present invention, as generally described and illustrated in the figures herein, may be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the present invention, presented in the accompanying drawings, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention.

Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Referring to fig. 1 to 5, the embodiment of the present invention provides a water sample collecting device for underground water engineering, which comprises a bearing mounting part 1, a collecting driving part 2 disposed on the upper half of the bearing mounting part 1, and a positioning collecting part 3 in transmission connection with the collecting driving part 2, the positioning and collecting component 3 comprises a connecting component 3a, a linkage component 3b and a plurality of collecting components 3c which are arranged in sequence along the vertical direction, linkage subassembly 3b and the equal swing joint of all collection subassemblies 3c, coupling assembling 3a runs through all collection subassemblies 3c in proper order and connects the shaping with all collection subassemblies 3c, and is a plurality of collection subassembly 3c can reciprocate, every along vertical direction the equal vertical upwards of collection end of collection subassembly 3c, the utility model discloses a theory of operation: because according to different detection requirements, sampling positions and sampling components at each time are different, because underground water needs to be sampled, the sampling depth is very deep, downlink power needs to be provided through other machines, the underground water sampling device is matched with a lifting hydraulic machine for use, firstly, the top of the bearing mounting component 1 is mounted to the output end of the lifting hydraulic machine, according to the preset sampling depth, all the acquisition components 3c are connected in series through the connecting component 3a, then, the side parts of all the acquisition components 3c are connected through the linkage component 3b, so that the positions of all the acquisition components 3c can be extended and contracted along the vertical direction, and then, the acquisition driving component 2 drives the acquisition component 3c close to the position to move, so that the positions of all the acquisition components 3c can be controlled, and further, the acquisition depth in the underground water acquisition process can be controlled, the sampling can be simultaneously carried out on different depths of the same underground water area, the problem that in the prior art, the sampling is complex due to repeated sampling for many times is solved, and the output of manpower and material resources is reduced.

Bear installing component 1 including bearing mounting panel 1a, drive mounting panel 1b, two symmetric distributions bearing mounting panel 1a top and can carry out the dismouting operation hang support plate 1c and a plurality of positioning support post 1d that are the rectangular structure and distribute bearing mounting panel 1a bottom, drive mounting panel 1 b's top and all positioning support post 1 d's bottom fixed connection bear mounting panel 1a and drive mounting panel 1b set up and can realize hanging support plate 1 c's installation and gather the installation operation of drive component 2, under operating condition, can provide stable prerequisite for the sampling operation.

Every gather subassembly 3c including gathering locating plate 3d, vertical location cover 3e and horizontal collection portion 3f, horizontal collection portion 3f sets up the top of gathering locating plate 3d, vertical location cover 3e cover is established on horizontal collection portion 3f and with the top fixed connection who gathers locating plate 3d, the both ends of gathering locating plate 3d top are equipped with the rectangle that supplies the collection end of horizontal collection portion 3f to deposit respectively and lead to groove 3d1, every the rectangle leads to groove 3d1 and all runs through collection locating plate 3d along vertical direction, and horizontal collection portion 3f sets up on gathering locating plate 3d, can accomplish the installation to horizontal collection portion 3f because vertical location cover 3e covers and can avoid soaking horizontal collection portion 3f in the collection in-process outside horizontal collection portion 3f, plays waterproof insulation's effect.

The transverse collecting part 3f comprises a bidirectional driving electric cylinder 3f1, two transverse driving clamps 3f2 and two collecting measuring cups 3f3, the bidirectional driving electric cylinder 3f1 is arranged at the top of the collecting positioning plate 3d, the two transverse driving clamps 3f2 are respectively arranged at two output ends of the bidirectional driving electric cylinder 3f1, the two collecting measuring cups 3f3 correspond to the two transverse driving clamps 3f2 in a one-to-one mode, each collecting measuring cup 3f3 is arranged in a rectangular through groove 3d1 in a non-working state, an opening of each collecting measuring cup 3f3 is upward, because each transverse collecting part 3f comprises the bidirectional driving electric cylinder 3f1, the two transverse driving clamps 3f2 and the two collecting measuring cups 3f3, when water sampling operation is needed, the two transverse driving electric cylinders 3f1 can drive the two transverse driving clamps 3f2 and the two collecting measuring cups 3f3 to move outwards along the horizontal direction, then two collection graduated flasks 3f3 all extend to the outside of whole device, the sampling of being convenient for, after water sampling is accomplished, rethread bidirectional drive electric cylinder 3f1 drives two transverse driving presss from both sides 3f2 and two collection graduated flasks 3f3 along the horizontal direction inwardly movable, retract to in the logical groove 3d1 of rectangle of gathering locating plate 3d, when retrieving whole sampling device, just can reduce the transverse contact area of whole device, then can avoid area of contact too big, and cause the damage of equipment.

Coupling assembling 3a includes four spliced poles 3a1 that are the distribution of rectangle structure, every the one end of spliced pole 3a1 and the bottom fixed connection of drive mounting panel 1b, spliced pole 3a 1's the other end runs through all collection locating plate 3d along vertical direction in proper order, and finally with bottommost collection locating plate 3d fixed connection, every gather locating plate 3d homoenergetic and slide on four spliced poles 3a1, the shaping is connected with all collection locating plate 3d to the setting of four spliced poles 3a1, every gather locating plate 3d homoenergetic and slide from top to bottom on four spliced poles 3a1, can realize gathering the operation to the water sample of the different degree of depth in same waters.

Linkage subassembly 3b includes that two symmetries set up all gather linkage portion 3g of locating plate 3d both sides, every linkage portion 3g includes connecting plate 3g1 that a plurality of groups intercrossing set up, every group connecting plate 3g1 all can change along vertical direction, all connecting plate 3g1 connects the shaping with one side of all gathering locating plate 3d, and a plurality of groups intercrossing's connecting plate 3g1 is the state of staggering each other, and this structure is prior art, can accomplish the position removal along vertical direction for all gathering locating plate 3d and provide necessary prerequisite guarantee, and all connecting plates 3g1 in this application are stainless steel and make, can use longer time in the groundwater.

The collecting and driving part 2 comprises a collecting and positioning electric cylinder 2a, a driving positioning plate 2b and two collecting and positioning columns 2c, the two collecting and positioning columns 2c are vertically arranged on a collecting and positioning plate 3d close to the driving mounting plate 1b, the bottom end of each collecting and positioning column 2c is fixedly connected with the top of the driving mounting plate 1b, the driving positioning plate 2b is arranged at the top of the two collecting positioning columns 2c, the collecting positioning electric cylinder 2a is arranged on the driving mounting plate 1b, the output shaft of the collecting and positioning electric cylinder 2a is vertically downward and is fixedly connected with the top of the driving positioning plate 2b, the collecting and positioning electric cylinder 2a is used as a power source for collecting water samples at different positions of the whole device, the collection positioning plate 3d close to the collection positioning electric cylinder 2a is pushed downwards along the vertical direction to move, so that the collection operation of water samples in different positions in the same water area is completed.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention.

Claims (7)

1. A water sample collection device for underground water engineering is characterized by comprising a bearing installation part (1), a collection driving part (2) arranged at the upper half part of the bearing installation part (1) and a positioning collection part (3) in transmission connection with the collection driving part (2), the positioning acquisition component (3) comprises a connecting component (3 a), a linkage component (3 b) and a plurality of acquisition components (3 c) which are sequentially arranged along the vertical direction, the linkage component (3 b) is movably connected with all the acquisition components (3 c), connecting assembly (3 a) run through all collection subassembly (3 c) in proper order and connect the shaping with all collection subassembly (3 c), and is a plurality of collection subassembly (3 c) can reciprocate, every along vertical direction the collection end of collection subassembly (3 c) is vertical upwards all.

2. The water sample collection device for underground water engineering according to claim 1, wherein the bearing and mounting component (1) comprises a bearing and mounting plate (1 a), a driving and mounting plate (1 b), two hanging and mounting plates (1 c) which are symmetrically distributed on the top of the bearing and mounting plate (1 a) and can be disassembled and assembled, and a plurality of positioning support columns (1 d) which are distributed on the bottom of the bearing and mounting plate (1 a) in a rectangular structure, and the top of the driving and mounting plate (1 b) is fixedly connected with the bottom ends of all the positioning support columns (1 d).

3. The device for collecting the water samples for the underground water engineering as claimed in claim 1, wherein each collecting component (3 c) comprises a collecting positioning plate (3 d), a vertical positioning cover (3 e) and a transverse collecting part (3 f), the transverse collecting part (3 f) is arranged at the top of the collecting positioning plate (3 d), the vertical positioning cover (3 e) is covered on the transverse collecting part (3 f) and is fixedly connected with the top of the collecting positioning plate (3 d), two ends of the top of the collecting positioning plate (3 d) are respectively provided with a rectangular through groove (3 d 1) for storing the collecting end of the transverse collecting part (3 f), and each rectangular through groove (3 d 1) penetrates through the collecting positioning plate (3 d) along the vertical direction.

4. A groundwater engineering water sample collection device as claimed in claim 3, wherein the transverse collection part (3 f) comprises a bidirectional driving electric cylinder (3 f 1), two transverse driving clamps (3 f 2) and two collection measuring cups (3 f 3), the bidirectional driving electric cylinder (3 f 1) is arranged at the top of the collection positioning plate (3 d), the two transverse driving clamps (3 f 2) are respectively arranged at the two output ends of the bidirectional driving electric cylinder (3 f 1), the two collection measuring cups (3 f 3) are in one-to-one correspondence with the two transverse driving clamps (3 f 2), each collection measuring cup (3 f 3) is arranged in a rectangular through groove (3 d 1) in an inoperative state, and the opening of each collection measuring cup (3 f 3) is upward.

5. A water sample collection device for underground water works as claimed in claim 2, wherein said connection assembly (3 a) comprises four connection columns (3 a 1) distributed in a rectangular structure, each of said connection columns (3 a 1) has one end fixedly connected to the bottom of the driving mounting plate (1 b), and the other end of said connection column (3 a 1) sequentially penetrates all the collection positioning plates (3 d) along the vertical direction, and finally is fixedly connected to the bottommost collection positioning plate (3 d), and each of said collection positioning plates (3 d) can slide on four connection columns (3 a 1).

6. A water sample collecting device for underground water engineering according to claim 3, characterized in that said linkage assembly (3 b) comprises two linkage portions (3 g) symmetrically arranged at both sides of all said collecting and positioning plates (3 d), each of said linkage portions (3 g) comprises a plurality of groups of connecting plates (3 g 1) arranged to cross each other, each group of said connecting plates (3 g 1) can be moved along the vertical direction, and all said connecting plates (3 g 1) connect and form one side of all collecting and positioning plates (3 d).

7. The device for collecting the water sample for the underground water engineering as claimed in claim 2, wherein the collecting and driving part (2) comprises a collecting and positioning electric cylinder (2 a), a driving positioning plate (2 b) and two collecting and positioning columns (2 c), the two collecting and positioning columns (2 c) are vertically mounted on a collecting and positioning plate (3 d) close to the driving mounting plate (1 b), the bottom end of each collecting and positioning column (2 c) is fixedly connected with the top of the driving mounting plate (1 b), the driving positioning plate (2 b) is mounted at the tops of the two collecting and positioning columns (2 c), the collecting and positioning electric cylinder (2 a) is arranged on the driving mounting plate (1 b), and the output shaft of the collecting and positioning electric cylinder (2 a) is vertically downward and fixedly connected with the top of the driving positioning plate (2 b).

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