CN211292714U - Oxygen concentration monitoring device for industrial recirculating aquaculture of Epinephelus akaara - Google Patents

Abstract

The utility model discloses an oxygen concentration monitoring devices that red some grouper was used in industrialization recirculating aquaculture, including dissolving oxygen analyzer and dissolving the probe line on the oxygen analyzer and the polarographic probe of probe line one end, dissolving one side fixedly connected with U-shaped protective case of oxygen analyzer, the polarographic probe is located the U-shaped protective case, rotates between the both sides inner wall of U-shaped protective case and installs same baffle, and the bottom of baffle establish to the arc structure and with the bottom inner wall movable contact of U-shaped protective case, the baffle is located one side that the oxygen analyzer was far away from to the polarographic probe, and one side bonding of dissolving oxygen analyzer is fixed with the first silica gel piece that is located the U-shaped protective case. The utility model relates to a rationally, convenient to use is convenient for accomodate the polarographic probe after the use and is sheltered from the protection, can form a complete face of sheltering from to the polarographic probe, effectively avoids exposing for a long time outside being blockked up the damage by dust debris and influence the detection accuracy nature, is favorable to the use.

Description

Oxygen concentration monitoring device for industrial recirculating aquaculture of Epinephelus akaara

Technical Field

The utility model relates to an oxygen concentration monitoring facilities technical field especially relates to an oxygen concentration monitoring devices that industrial recirculating water aquaculture red some grouper was used.

Background

The dissolved oxygen analyzer is a precise dissolved oxygen analyzer for monitoring and testing dissolved oxygen, and is an oxygen concentration monitoring device suitable for water culture, such as a dissolved oxygen analyzer with the model D0-5510 on the market, a polarographic probe with a temperature sensor is worn on the dissolved oxygen analyzer, so that the Dissolved Oxygen (DO) measurement, the oxygen content (O2) measurement and the temperature measurement in the air can be accurately carried out, and the dissolved oxygen analyzer can be applied to aquariums, fish culture tanks, glass fish ponds, mining industry, medical research, agriculture, laboratories, water environments and the like, and can be suitable for monitoring and testing the oxygen concentration in water when industrial circulating water is used for culturing Epinephelus akaara;

but it still has some insufficiencies, and its polarographic probe is not convenient for accomodate after the use and shelters from the protection, directly exposes outside when moving after the use and carry and is blockked up by external debris dust easily, leads to desensitization, influences the accuracy nature of monitoring, can not satisfy the user demand, to this phenomenon, therefore we have proposed the oxygen concentration monitoring devices that industrialization recirculating water aquaculture red some grouper was used.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the defects existing in the prior art and providing an oxygen concentration monitoring device for industrial recirculating aquaculture of epinephelus akaara.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the oxygen concentration monitoring device for industrial recirculating aquaculture of Epinephelus akaara comprises a dissolved oxygen analyzer, a probe line on the dissolved oxygen analyzer and a polarographic probe at one end of the probe line, wherein one side of the dissolved oxygen analyzer is fixedly connected with a U-shaped protective shell, the polarographic probe is positioned in the U-shaped protective shell, a baffle is rotatably arranged between the inner walls of the two sides of the U-shaped protective shell, the bottom of the baffle is of an arc structure and is movably contacted with the inner wall of the bottom of the U-shaped protective shell, the baffle is positioned at one side of the polarographic probe far away from the dissolved oxygen analyzer, a first silica gel block positioned in the U-shaped protective shell is fixedly bonded at one side of the dissolved oxygen analyzer, a second silica gel block is fixedly bonded at the top of one side of the baffle close to the dissolved oxygen analyzer, the movable contact of one side of the second silica gel block and the first silica gel block close to each other is arranged as an arc surface matched with the outer side of the probe line, two arcwall faces all with the outside movable contact of probe line, the draw-in groove has all been seted up to the top both sides of U-shaped protective case, the rectangular channel has been seted up at the top of baffle, and sliding sleeve is equipped with the rectangular rod in the rectangular channel, the top of rectangular rod extends to the top and the fixedly connected with horizontal pole of baffle, the top fixedly connected with pull ring of horizontal pole, the equal fixedly connected with kelly in bottom both sides of horizontal pole, and establish to the toper structure in the draw-in groove that extends to the correspondence in the bottom of kelly, the kelly blocks the dress mutually with the draw-in groove that corresponds, the same movable sleeve of fixedly connected with is established at the spring on the rectangular rod.

Preferably, a limit stop is fixedly connected to the inner wall of the rear side of the U-shaped protective shell, and one side of the limit stop, which is far away from the dissolved oxygen analyzer, is in movable contact with the bottom of one side of the baffle.

Preferably, the same round shaft is fixedly connected between the inner wall of the front side and the inner wall of the rear side of the U-shaped protective shell, a round hole is formed in the bottom of the front side of the baffle, two bearings are fixedly sleeved in the round hole, and inner rings of the bearings are fixedly sleeved with the outer side of the round shaft.

Preferably, the front side and the rear side of the first silica gel block are respectively bonded and fixed with the front side inner wall and the rear side inner wall of the U-shaped protective shell.

Preferably, the front side and the rear side of the baffle are respectively in movable contact with the front side inner wall and the rear side inner wall of the U-shaped protective shell.

Preferably, the front side and the rear side of the second silica gel block are respectively in movable contact with the front side inner wall and the rear side inner wall of the U-shaped protective shell.

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

through the matching of the dissolved oxygen analyzer, the probe line, the polarographic probe, the U-shaped protective shell, the baffle, the first silica gel block, the second silica gel block, the rectangular groove, the rectangular rod, the transverse rod, the pull ring, the spring, the clamping groove, the clamping rods and the limit stop with the circular shaft, the pull ring is pulled upwards to drive the rectangular rod to slide upwards in the rectangular groove through the transverse rod and stretch the spring, the transverse rod drives the two clamping rods to be separated from the two clamping grooves upwards, the pull ring moving rightwards drives the baffle to rotate rightwards to be turned over through the matching of the transverse rod and the rectangular rod, the baffle drives the second silica gel block to rotate rightwards from the U-shaped protective shell, at the moment, the polarographic probe can be moved rightwards, and when the probe is stored, the polarographic probe is moved into the U-shaped protective shell from the right side, the pull ring is pulled again to drive the transverse rod to stretch the spring, then the baffle rotates leftwards, the baffle drives the cambered surface of, the spring that is in tensile state at this moment resets and drives two kellies through the horizontal pole and insert two draw-in grooves downwards, can fixed stop, and the arcwall face of first silica gel piece and the arc of second silica gel piece form the laminating and surround in the outside of the probe line this moment, and baffle, U-shaped protective case and dissolved oxygen analyzer of deuterogamying can form a complete face of sheltering from, reach and accomodate the mesh that shelters from the protection to utmost point spectrum probe.

The utility model relates to a rationally, convenient to use is convenient for accomodate the polarographic probe after the use and is sheltered from the protection, can form a complete face of sheltering from to the polarographic probe, effectively avoids exposing for a long time outside being blockked up the damage by dust debris and influence the detection accuracy nature, is favorable to the use.

Drawings

FIG. 1 is a schematic structural view of an oxygen concentration monitoring device for industrial recirculating aquaculture of Epinephelus akaara;

FIG. 2 is a schematic view of a partial sectional structure A of an oxygen concentration monitoring device for industrial recirculating aquaculture of Epinephelus akaara;

FIG. 3 is a schematic side sectional view of the U-shaped protective shell, the baffle, the cross bar, the rectangular bar and the clamping bar connecting piece of the oxygen concentration monitoring device for industrial recirculating aquaculture of Epinephelus akaara provided by the utility model;

fig. 4 is a schematic view of the first silica gel block and the second silica gel block connecting piece of the oxygen concentration monitoring device for industrial recirculating aquaculture of epinephelus akaara.

In the figure: 1 dissolved oxygen analyzer, 2 probe lines, 3 polarographic probes, 4U-shaped protective shells, 5 baffles, 6 first silica gel blocks, 7 second silica gel blocks, 8 rectangular grooves, 9 rectangular rods, 10 cross rods, 11 pull rings, 12 springs, 13 clamping grooves, 14 clamping rods, 15 limit stops and 16 round shafts.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Referring to fig. 1-4, the oxygen concentration monitoring device for industrial recirculating aquaculture of Epinephelus akaara comprises an oxygen analyzer 1, a probe line 2 on the oxygen analyzer 1, and a polarographic probe 3 at one end of the probe line 2, wherein one side of the oxygen analyzer 1 is fixedly connected with a U-shaped protective shell 4, the polarographic probe 3 is positioned in the U-shaped protective shell 4, a baffle 5 is rotatably arranged between the inner walls of the two sides of the U-shaped protective shell 4, the bottom of the baffle 5 is of an arc structure and is movably contacted with the inner wall of the bottom of the U-shaped protective shell 4, the baffle 5 is positioned at one side of the polarographic probe 3 far away from the oxygen analyzer 1, a first silica gel block 6 positioned in the U-shaped protective shell 4 is fixedly bonded at one side of the oxygen analyzer 1, a second silica gel block 7 is fixedly bonded at the top of one side of the baffle 5 close to the oxygen analyzer 1, and one side of the second silica gel block 7 close to the first silica gel block 6 are movably contacted, one side of the second silica gel block 7, which is close to the first silica gel block 6, is arranged to be an arc surface which is matched with the outer side of the probe line 2, the two arc surfaces are movably contacted with the outer side of the probe line 2, two sides of the top of the U-shaped protective shell 4 are respectively provided with a clamping groove 13, the top of the baffle 5 is provided with a rectangular groove 8, a rectangular rod 9 is sleeved in the rectangular groove 8 in a sliding way, the top end of the rectangular rod 9 extends to the upper side of the baffle 5 and is fixedly connected with a cross rod 10, the top of the cross rod 10 is fixedly connected with a pull ring 11, two sides of the bottom of the cross rod 10 are respectively and fixedly connected with a clamping rod 14, the bottom end of the clamping rod 14 extends to the corresponding clamping groove 13 and is arranged to be a conical structure, the clamping rod 14 is clamped with the corresponding clamping groove 13, and the spring 12 which is sleeved on the rectangular rod 9 in a same movable way is fixedly connected between the bottom of the cross rod 10, can form a complete shielding face to polarographic probe 3, effectively avoid exposing for a long time outside and being blockked up the damage by dust debris and influence detection accuracy nature, be favorable to the use.

In the utility model, a limit stop 15 is fixedly connected on the rear inner wall of the U-shaped protective shell 4, one side of the limit stop 15 far away from the dissolved oxygen analyzer 1 is movably contacted with the bottom of one side of the baffle 5, the same round shaft 16 is fixedly connected between the front inner wall and the rear inner wall of the U-shaped protective shell 4, a round hole is arranged at the bottom of the front side of the baffle 5, two bearings are fixedly sleeved in the round hole, the inner ring of the bearing is fixedly sleeved with the outer side of the round shaft 16, the front side and the rear side of the first silica gel block 6 are respectively fixedly bonded with the front inner wall and the rear inner wall of the U-shaped protective shell 4, the front side and the rear side of the baffle 5 are respectively movably contacted with the front inner wall and the rear inner wall of the U-shaped protective shell 4, the front side and the rear side of the second silica gel block 7 are respectively movably contacted with the front inner wall and the rear inner wall of the U-shaped protective shell 4, the utility model has reasonable design and convenient use, and is convenient for probe storage and protection of the, can form a complete shielding face to polarographic probe 3, effectively avoid exposing for a long time outside and being blockked up the damage by dust debris and influence detection accuracy nature, be favorable to the use.

The working principle is as follows: when the polarographic probe 3 needs to be taken out, the pull ring 11 is pulled upwards to drive the cross rod 10 to move upwards, the cross rod 10 drives the rectangular rod 9 to slide upwards in the rectangular groove 8 and stretch the spring 12, meanwhile, the cross rod 10 drives the two clamping rods 14 to be separated upwards from the two clamping grooves 13, the pull ring 11 moving rightwards next drives the cross rod 10 to rotate rightwards, the cross rod 10 drives the baffle 5 to rotate rightwards in the circular shaft 16 through the rectangular rod 9, the baffle 5 drives the second silica gel block 7 to rotate rightwards out of the U-shaped protective shell 4, at the moment, the baffle 5 is rotated rightwards to be turned over, and at the moment, the polarographic probe 3 moving rightwards can be moved out of the U-shaped protective shell 4;

when the polarographic probe is stored after being used, the polarographic probe 3 is moved into the U-shaped protective shell 4 from the right side, when the outer side of the probe line 2 at the top of the polarographic probe 3 is contacted with the arc-shaped surface on the first silica gel block 6, the pull ring 11 is pulled again to drive the cross rod 10 to stretch the spring 12, then the pull ring 11 is moved to drive the cross rod 10 to rotate leftwards, the cross rod 10 drives the baffle 5 to rotate leftwards through the rectangular rod 9, the baffle 5 drives the second silica gel block 7 to rotate rightwards into the U-shaped protective shell 4, when the bottom of one side of the baffle 5 rotates to be contacted with the limit stop block 15, the arc-shaped surface of the second silica gel block 7 is also contacted with the outer side of the probe line 2, the pulling force on the pull ring 11 is released, the spring 12 in the stretching state is reset to drive the cross rod 10 to move downwards, the cross rod 10 drives the two clamping rods 14 to be inserted downwards into the two clamping, horizontal pole 10 passes through rectangular rod 9 restriction baffle 5 this moment, can fixed stop 5, and the arcwall face of first silica gel piece 6 and the arc of second silica gel piece 7 form the laminating and surround in the outside of probe line 2 this moment, and baffle 5, U-shaped protective case 4 and dissolved oxygen analyzer 1 of deuterogamying can form a complete face of sheltering from, reach and accomodate the mesh of sheltering from the protection to polarographic probe 3, can effectively avoid the dust foreign matter to get into and cause jam and damage to polarographic probe 3.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (6)

1. Oxygen concentration monitoring devices that industrialization recirculating water aquaculture red some grouper was used, including dissolving oxygen analysis appearance (1) and dissolving oxygen analysis appearance probe line (2) and probe line (2) one end polarographic probe (3) on oxygen analysis appearance (1), its characterized in that, one side fixedly connected with U-shaped protective case (4) of oxygen analysis appearance (1), polarographic probe (3) are located U-shaped protective case (4), rotate between the both sides inner wall of U-shaped protective case (4) and install same baffle (5), and the bottom of baffle (5) is established to the arc structure and with the bottom inner wall movable contact of U-shaped protective case (4), baffle (5) are located one side that polarographic probe (3) are far away from dissolved oxygen analysis appearance (1), one side bonding of dissolved oxygen analysis appearance (1) is fixed with first silica gel piece (6) that are located U-shaped protective case (4), baffle (5) are close to one side top bonding of dissolved oxygen analysis appearance (1) and are fixed with second silica gel piece (7), one side of the second silica gel block (7) close to the first silica gel block (6) is movably contacted, one side of the second silica gel block (7) close to the first silica gel block (6) is respectively arranged as an arc-shaped surface matched with the outer side of the probe line (2), the two arc-shaped surfaces are movably contacted with the outer side of the probe line (2), the two sides of the top of the U-shaped protective shell (4) are respectively provided with a clamping groove (13), the top of the baffle (5) is provided with a rectangular groove (8), a rectangular rod (9) is sleeved in the rectangular groove (8) in a sliding manner, the top end of the rectangular rod (9) extends to the upper side of the baffle (5) and is fixedly connected with a transverse rod (10), the top of the transverse rod (10) is fixedly connected with a pull ring (11), the two sides of the bottom of the transverse rod (10) are respectively and fixedly connected with a clamping rod (14), and the bottom end of the clamping rod (14) extends into, the clamping rods (14) are clamped with the corresponding clamping grooves (13), and a spring (12) movably sleeved on the rectangular rod (9) is fixedly connected between the bottom of the cross rod (10) and the top of the baffle (5).

2. The oxygen concentration monitoring device for industrial recirculating aquaculture of Epinephelus akaara as claimed in claim 1, wherein a limit stop (15) is fixedly connected to the inner wall of the rear side of the U-shaped protective shell (4), and one side of the limit stop (15) far away from the dissolved oxygen analyzer (1) is in movable contact with the bottom of one side of the baffle (5).

3. The oxygen concentration monitoring device for industrial recirculating aquaculture of Epinephelus akaara as claimed in claim 1, wherein the same circular shaft (16) is fixedly connected between the front inner wall and the rear inner wall of the U-shaped protective shell (4), the bottom of the front side of the baffle (5) is provided with a circular hole, two bearings are fixedly sleeved in the circular hole, and the inner rings of the bearings are fixedly sleeved with the outer sides of the circular shaft (16).

4. The oxygen concentration monitoring device for industrial recirculating aquaculture of Epinephelus akaara as claimed in claim 1, wherein the front side and the rear side of the first silica gel block (6) are respectively fixed with the front side inner wall and the rear side inner wall of the U-shaped protective shell (4) in an adhering manner.

5. The oxygen concentration monitoring device for industrial recirculating aquaculture of Epinephelus akaara as claimed in claim 1, wherein the front and rear sides of the baffle plate (5) are in movable contact with the inner wall of the U-shaped casing (4).

6. The oxygen concentration monitoring device for industrial recirculating aquaculture of Epinephelus akaara as claimed in claim 1, wherein the front side and the rear side of the second silica gel block (7) are respectively in movable contact with the inner wall of the front side and the inner wall of the rear side of the U-shaped protective shell (4).

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