CN217586886U - Flow cell for electrolyte analysis - Google Patents

Abstract

The utility model discloses a flow-through cell for electrolyte analysis relates to chemistry experiment apparatus technical field. The utility model comprises a circulating tank body and an auxiliary observation mechanism connected to the central position of the upper end surface of the circulating tank body; the auxiliary observation mechanism comprises a transparent observation window, a group of power supply seats connected to the front and rear parts of the upper end surface of the transparent observation window and an LED lamp electrically connected to the middle part of the inner side surface of the power supply seat; the energy-saving power supply device also comprises an energy-saving power supply mechanism which is connected to the middle part of the outer side surface of the power supply seat and the upper front part of the circulating pool body. The utility model discloses a set up supplementary observation mechanism and energy-conserving power supply mechanism, solved current circulation pond, generally need open the pond lid to carry out the learning of the interior liquid circulation condition of circulation pond, the operation is loaded down with trivial details, influences the result of use, or adopts the outer supplementary structure of looking over, but the structure that is used for the illumination too relies on the domestic power consumption, and energy-conserving measure is not enough, increases use cost's problem.

Description

Flow cell for electrolyte analysis

Technical Field

The utility model belongs to the technical field of chemistry experiment apparatus, especially, relate to a flow-through cell for electrolyte analysis.

Background

The electrolyte is a compound that is soluble in an aqueous solution or capable of conducting electricity in a molten state. The flow cell can be divided into strong electrolyte and weak electrolyte according to the ionization degree, almost all ionized electrolyte is strong electrolyte, only a small part ionized electrolyte is weak electrolyte, and the flow cell belongs to the equipment used in electrolyte analysis.

However, the following disadvantages still exist in the practical use:

1. the existing flow-through cell generally needs to open a cell cover to know the liquid flow condition in the flow-through cell, so that the operation is complicated and the using effect is influenced;

2. the existing flow cell or an external auxiliary viewing structure is adopted, but the structure for lighting is too dependent on domestic electricity, so that energy-saving measures are insufficient, and the use cost is increased.

Therefore, the current flow cell for electrolyte analysis cannot meet the requirement of practical use, so that the market needs improved technology to solve the above problems.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a circulation pond for electrolyte analysis through setting up supplementary observation mechanism and energy-conserving power supply mechanism, has solved current circulation pond, generally need open the pond lid to carry out learning of the liquid circulation condition in the circulation pond, the operation is loaded down with trivial details, influences the result of use, or adopts the outer supplementary structure of looking over, but the structure that is used for the illumination too relies on the power consumption of living, and energy-conserving measure is not enough, increases use cost's problem.

In order to solve the technical problem, the utility model discloses a realize through following technical scheme:

the utility model relates to a flow cell for electrolyte analysis, which comprises a flow cell body and an auxiliary observation mechanism connected to the central position of the upper end surface of the flow cell body;

the auxiliary observation mechanism comprises a transparent observation window, a group of power supply seats connected to the front and rear parts of the upper end surface of the transparent observation window and an LED lamp electrically connected to the middle part of the inner side surface of each power supply seat;

the energy-saving power supply device also comprises an energy-saving power supply mechanism which is connected to the middle part of the outer side surface of the power supply seat and the upper front part of the circulating pool body.

Furthermore, the energy-saving power supply mechanism comprises a storage battery box connected to the middle part of the outer side surface of the power supply seat and a photovoltaic panel connected to the upper front part of the circulating cell body through a support;

the storage battery box is internally provided with a storage battery, and a lead extends through the middle part of one side of a box cover clamped at the upper end of the storage battery box; the photovoltaic electroplax is supported and fixed by the support to absorb external illumination through the photovoltaic electroplax and generate electricity, and save through the battery, be used for supplying power, energy-concerving and environment-protective to the LED lamp.

Furthermore, the flow cell body comprises an electrode holder, a seat cover clamped in the middle of the upper end of the electrode holder and connecting pipes which are connected with the centers of the lower parts of the two side surfaces of the electrode holder in an equidistant penetrating manner;

the front end of the connecting pipe is arranged in a damping sealing plug mode, and the inner bottom end of the middle cavity of the electrode base is arranged in a partition plate mode, wherein the partition plate is welded at equal intervals; the cavity in the middle of the electrode seat is used for receiving liquid, the connecting pipe is used for connecting an external pipeline for conveying and outputting the liquid, and the sealing plug is used for carrying out external sealing treatment on the connecting pipe in use and carrying out independent isolation on the space in the cavity through the equidistant partition plate so as to carry out multi-channel circulation of the liquid.

Furthermore, a supporting mechanism is connected to the center of the bottom end face of the electrode base, and the supporting mechanism comprises a support and a support block connected to the bottom end of the support in a damping manner;

the front end and the rear end of the two sides of the bracket are arranged in a penetrating stud, and the bottom surfaces of the supporting blocks are arranged in equidistant anti-skidding blocks; the support block structure is fixed under the stud of the support, the support block is arranged at a designated position, and the electrode holder can be improved in structural stability by the contact of the anti-slip block and the ground.

Furthermore, the front lower end and the rear lower end of the electrode holder are connected with a moving mechanism, and the moving mechanism comprises a mounting frame, an air cylinder penetrating through the middle part of the upper front end of the mounting frame, a U-shaped frame connected to the output end of the bottom of the air cylinder and a plurality of moving wheels connected to the lower part of the inner side surface of the U-shaped frame; the cylinder applies downward force to the U-shaped frame, after the moving wheel is contacted with the outer structure, the height of the electrode seat is raised under the application of continuous force, and at the moment, the pushing force is applied to the electrode seat, so that the position can be moved.

Furthermore, the lower parts of two side surfaces of the U-shaped frame are arranged in a penetrating shaft seat, the inner side of the shaft seat is connected with a shaft rod, and the plurality of movable wheels are sleeved on the shaft rod; the shaft seat is used for bearing the shaft rod, and the shaft rod is used for bearing the plurality of movable wheels.

The utility model discloses following beneficial effect has:

1. the utility model discloses a set up supplementary observation mechanism, carry out the addding of observation window to seat cover upper end middle part, easily carry out clear real-time looking over to circulation liquid in the electrode holder, and the LED lamp of addding can provide light under dim environment, easily carries out the use of observation window.

2. The utility model discloses a set up energy-conserving power supply mechanism, adopt the mode of photovoltaic electroplax power supply, replace traditional domestic power consumption power supply mode, energy-concerving and environment-protective, easy to use reduces use cost.

Drawings

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

Fig. 1 is a side view of the present invention;

fig. 2 is a bottom view of the electrode holder of the present invention;

fig. 3 is a structural diagram of the moving mechanism of the present invention.

In the drawings, the components represented by the respective reference numerals are listed below:

100. a flow-through cell body; 110. an electrode holder; 120. taking over a pipe; 130. a seat cover; 200. a moving mechanism; 210. a mounting frame; 220. a cylinder; 230. a U-shaped frame; 240. a moving wheel; 300. a support mechanism; 310. a support; 320. supporting a block; 400. an auxiliary observation mechanism; 410. an observation window; 420. a power supply base; 430. an LED lamp; 500. an energy-saving power supply mechanism; 510. a battery case; 520. a support; 530. photovoltaic panel.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

Referring to fig. 1-3, the present invention relates to a flow cell for electrolyte analysis, which comprises a flow cell body 100 and an auxiliary observation mechanism 400 connected to the center of the upper end surface of the flow cell body 100;

the auxiliary observation mechanism 400 comprises a transparent observation window 410, a group of power supply seats 420 connected to the front and rear parts of the upper end surface of the transparent observation window 410 and LED lamps 430 electrically connected to the middle parts of the inner side surfaces of the power supply seats 420;

the energy-saving power supply device further comprises an energy-saving power supply mechanism 500 connected to the middle part of the outer side surface of the power supply seat 420 and the upper front part of the flow cell body 100;

the auxiliary observation mechanism 400 is used, the liquid circulating in the cavity in the electrode holder 110 is checked clearly in real time through the observation window 410 in advance, and when the checked environment is in darkness, the switch of the LED lamp 430 is turned on, and the checking after the illumination operation is carried out is completed.

As shown in fig. 1, the energy-saving power supply mechanism 500 includes a storage battery box 510 connected to the middle of the outer side surface of the power supply base 420 and a photovoltaic panel 530 connected to the upper front of the flow-through cell body 100 through a support 520;

the storage battery box 510 is provided with a built-in storage battery, and a lead extends through the middle of one side of a box cover clamped at the upper end of the storage battery box 510;

carry out the use of energy-conserving power supply mechanism 500, carry out putting into of battery in advance to battery box 510, at this moment, carry out the joint of case lid to battery box 510 upper end, and extend the wire, and carry out being connected with photovoltaic electroplax 530, then, carry out the placing of assigned position to photovoltaic electroplax 530 through support 520, when carrying out the electricity generation after the illumination absorption through photovoltaic electroplax 530, save through the battery, and the power supply that is used for LED lamp 430 can.

As shown in fig. 2, the flow-through cell body 100 comprises an electrode holder 110, a seat cover 130 clamped in the middle of the upper end of the electrode holder 110, and a connection tube 120 equidistantly penetrating the center of the lower part of the two side surfaces of the electrode holder 110;

the front end of the connecting pipe 120 is arranged as a damping sealing plug, and the inner bottom end of the middle cavity of the electrode holder 110 is arranged as a partition plate welded at equal intervals;

when the flow-through cell body 100 is used, the sealing plug is separated in advance, and at the moment, the connecting pipe 120 is connected with the external conveying pipe so as to circulate the external liquid into a plurality of channels formed by the partition plates;

the center of the bottom end surface of the electrode holder 110 is connected with a supporting mechanism 300, and the supporting mechanism 300 comprises a bracket 310 and a supporting block 320 connected to the bottom end of the bracket 310 in a damping manner;

the front end and the rear end of the two sides of the bracket 310 are arranged in a penetrating stud, and the bottom surfaces of the supporting blocks 320 are arranged in equidistant anti-skidding blocks;

when the supporting mechanism 300 is used, the upper end of the supporting block 320 is placed in the bracket 310, the stud on the bracket 310 is applied with a tightening force, the supporting block 320 is installed and fixed, and at this time, the anti-skid block on the bottom end face of the supporting block 320 is placed at a designated position.

As shown in fig. 3, the front and rear lower ends of the electrode holder 110 are connected to a moving mechanism 200, and the moving mechanism 200 includes a mounting frame 210, an air cylinder 220 penetrating the middle of the upper front end of the mounting frame 210, a U-shaped frame 230 connected to the bottom output end of the air cylinder 220, and a plurality of moving wheels 240 connected to the lower portion of the inner side of the U-shaped frame 230;

the lower parts of the two side surfaces of the U-shaped frame 230 are arranged in a penetrating shaft seat, the inner side of the shaft seat is connected with a shaft rod, and the plurality of moving wheels 240 are sleeved on the shaft rod;

when the moving mechanism 200 is used, the air cylinder 220 applies downward force to the U-shaped frame 230 at the external control end, at this time, the U-shaped frame 230 drives the moving wheel 240 to move downward and slide in the mounting frame 210, after the moving wheel 240 contacts with the external structure, the device is lifted under the application of continuous force, and then the pushing force is applied, so that the device can move.

The above is only the preferred embodiment of the present invention, and the present invention is not limited thereto, any technical solutions recorded in the foregoing embodiments are modified, and some technical features thereof are replaced with equivalent ones, and any modification, equivalent replacement, and improvement made thereby all belong to the protection scope of the present invention.

Claims (6)

1. A flow-through cell for electrolyte analysis, comprising a flow-through cell body (100) and an auxiliary observation mechanism (400) connected to a central position of an upper end face of the flow-through cell body (100);

the auxiliary observation mechanism (400) is characterized by comprising a transparent observation window (410), a group of power supply seats (420) connected to the front part and the rear part of the upper end surface of the transparent observation window (410) and an LED lamp (430) electrically connected to the middle part of the inner side surface of the power supply seat (420);

the energy-saving power supply device also comprises an energy-saving power supply mechanism (500) which is connected to the middle part of the outer side surface of the power supply seat (420) and the upper front part of the circulating pool body (100).

2. A flow cell for electrolyte analysis according to claim 1, characterized in that the energy-saving power supply mechanism (500) comprises a storage battery box (510) connected to the middle of the outer side of the power supply base (420) and a photovoltaic panel (530) connected to the front of the flow cell body (100) through a support (520);

the storage battery box (510) is provided with a built-in storage battery, and a wire penetrates through the middle of one side of the box cover clamped at the upper end of the storage battery box (510) and extends.

3. The flow cell for electrolyte analysis according to claim 1, wherein the flow cell body (100) comprises an electrode holder (110), a seat cover (130) clamped in the middle of the upper end of the electrode holder (110), and connecting tubes (120) which are equidistantly connected in the center of the lower parts of the two side surfaces of the electrode holder (110);

the front end of the connecting pipe (120) is provided with a damping sealing plug, and the inner bottom end of the middle cavity of the electrode holder (110) is provided with a partition plate welded at equal intervals.

4. A flow cell for electrolyte analysis according to claim 3, wherein a support mechanism (300) is connected to the central position of the bottom end surface of the electrode holder (110), and the support mechanism (300) comprises a bracket (310) and a support block (320) connected to the bottom end of the bracket (310) in a damping manner;

the front end and the rear end of support (310) both sides are the double-screw bolt setting that runs through, and prop up the setting of non slipping spur of equidistance of piece (320) bottom surface.

5. The flow cell for electrolyte analysis according to claim 3, wherein the lower end of the electrode holder (110) is connected with a moving mechanism (200), and the moving mechanism (200) comprises a mounting frame (210), a cylinder (220) penetrating the middle of the upper front end of the mounting frame (210), a U-shaped frame (230) connected to the lower output end of the cylinder (220), and a plurality of moving wheels (240) connected to the lower portion of the inner side of the U-shaped frame (230).

6. The flow cell for electrolyte analysis according to claim 5, wherein the lower portion of the two sides of the U-shaped frame (230) is a through axle seat, and the axle is connected to the inside of the axle seat, and the plurality of moving wheels (240) are sleeved on the axle.

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