CN215115861U - Electrolytic copper foil chloride ion detection device - Google Patents

Abstract

The utility model discloses a detection apparatus for electrolytic copper foil chloride ion, including instrument body, lid, display screen and button, sample room and cell standing groove have been seted up on the instrument body, the inslot of sample room is equipped with slide positioning mechanism, slide positioning mechanism includes sample storage rack, apron, fixed block, compression spring, fender ring, dop and fixed plate, two the inslot of cell standing groove is equipped with the cell storage rack. A detection device of electrolytic copper foil chloride ion, belong to the detection device field, through the slide positioning mechanism who sets up, the mode that adopts slide positioning is on with the sample storage rack placed wait to detect the sample direct movement to with the light path place on the same parallel line position, whole easy operation is swift, can also avoid simultaneously spilling at the in-process sample that removes to improve work efficiency greatly, the cell storage rack that sets up simultaneously makes things convenient for the cell to access.

Description

Electrolytic copper foil chloride ion detection device

Technical Field

The utility model relates to a detection device field, in particular to electrolytic copper foil chloride ion's detection device.

Background

In the preparation and production of copper foil, the additive has a great influence on the properties of the copper foil. The chloride ions react with the copper ions in the solution to generate cuprous chloride (CuCl) colloidal particles to inhibit the influence of the copper ions, and the chloride ions also have the function of a brightening agent to influence the conversion and crystallization speed of the copper, so that the cathode polarization is improved, and the grain structure and the surface of the copper foil are uniform and fine. Therefore, the detection of the concentration of the chloride ions is a crucial link in the production process of the electrolytic copper foil. What tradition all adopted visible spectrophotometer to detect, but when using this instrument, need will wait to detect the sample and adjust to remove to with the light path on same parallel line position, lead to operating slowly when detecting for detection efficiency greatly reduced, and when the removal is waiting to detect the sample, if the range of operation is too big, can lead to solution to produce in inside and rock and spill.

SUMMERY OF THE UTILITY MODEL

The main object of the utility model is to provide a detection device for electrolytic copper foil chloride ion, can effectively solve the problem in the background art.

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

the utility model provides a detection apparatus for electrolytic copper foil chloride ion, includes instrument body, lid, display screen and button, sample room and cell standing groove have been seted up on the instrument body, the inslot of sample room is equipped with slide positioning mechanism, slide positioning mechanism includes sample storage rack, apron, fixed block, compression spring, fender ring, dop and fixed plate, two be equipped with the cell storage rack in the groove of cell standing groove.

Preferably, a set of symmetrical installation clamping strips are respectively and fixedly installed on two sides of the groove wall of the cuvette placing groove, a through hole is formed in the front end of the outer wall of the instrument body, and the through hole is communicated with the sample chamber.

Preferably, a set of symmetrical vertical installation clamping grooves are respectively formed in the side walls of the two sides of the cuvette storage rack, the installation clamping grooves correspond to the installation clamping strips, and the convex blocks are fixedly installed on the top surface of the cuvette storage rack.

Preferably, the fixed plates are fixedly mounted on two sides of the bottom surface in the groove of the sample chamber respectively, the top surface of each fixed plate is provided with a T-shaped sliding groove, and the inner side wall of each fixed plate is provided with a positioning groove.

Preferably, the top surface fixed mounting of sample storage rack has the locating piece of two sets of symmetries, fixed mounting has the connecting rod on the front end wall of sample storage rack, and the connecting rod passes the through-hole, the front end fixed mounting of connecting rod has the pull ring, the bottom surface fixed mounting of sample storage rack has the T type sliding block of symmetry, T type sliding block movable mounting is in T type sliding tray.

Preferably, the bottom surface fixed mounting of sample storage rack has the fixed block, logical groove has been seted up on the lateral wall of fixed block, the inslot movable mounting who leads to the groove has compression spring, compression spring's both ends fixed mounting has the dop, the both ends notch punishment that leads to the groove do not fixed mounting have the fender ring, the dop passes the fender ring, the locating hole of two sets of symmetries is seted up to the top surface of apron, and locating hole and locating piece correspond each other.

Compared with the prior art, the utility model discloses following beneficial effect has:

the utility model discloses in, through the slide positioning mechanism who sets up, the mode that adopts slide positioning is with placing on the sample storage rack wait that the sample direct movement is to with the same parallel line position at light path place on, whole easy operation is swift, can also avoid spilling at the in-process sample that removes simultaneously to improve work efficiency greatly, the cell storage rack that sets up simultaneously makes things convenient for the cell to access.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention;

fig. 2 is a schematic diagram of the overall structure of the present invention;

FIG. 3 is an enlarged schematic view of the structure of the cuvette holding groove of the present invention;

FIG. 4 is a schematic view of the overall structure of the cuvette storage rack of the present invention;

fig. 5 is a schematic view of the sliding positioning mechanism according to the present invention.

In the figure: 1. an instrument body; 2. a cover; 3. a display screen; 4. pressing a key; 5. a sample chamber; 6. a slide positioning mechanism; 7. a cuvette storage rack; 8. a cuvette holding groove; 9. installing a clamping strip; 10. a through hole; 11. installing a clamping groove; 12. a raised block; 13. a sample storage rack; 14. positioning blocks; 15. a cover plate; 16. positioning holes; 17. a T-shaped sliding block; 18. a connecting rod; 19. a pull ring; 20. a fixed block; 21. a through groove; 22. a compression spring; 23. a baffle ring; 24. clamping a head; 25. a fixing plate; 26. a T-shaped sliding groove; 27. and (6) positioning a groove.

Detailed Description

In order to make the technical means, creation features, achievement purposes and functions of the present invention easy to understand, the present invention is further described below with reference to the following embodiments.

As shown in fig. 1-2, a device for detecting chloride ions in electrolytic copper foil comprises an instrument body 1, a cover 2, a display screen 3 and keys 4, wherein the instrument body 1 is provided with a sample chamber 5 and a cuvette holding groove 8, a sliding positioning mechanism 6 is arranged in the groove of the sample chamber 5, the sliding positioning mechanism 6 comprises a sample storage rack 13, a cover plate 15, a fixing block 20, a compression spring 22, a baffle ring 23, a clamping head 24 and a fixing plate 25, and cuvette storage racks 7 are arranged in the grooves of the two cuvette holding grooves 8.

As shown in fig. 3-4, in this embodiment, in order to facilitate the storage and taking of the cuvettes, a set of symmetrical mounting strips 9 is respectively and fixedly mounted on two sides of a groove wall of the cuvette holding groove 8, a through hole 10 is formed in the front end of an outer wall of the instrument body 1, the through hole 10 is communicated with the sample chamber 5, a set of symmetrical vertical mounting slots 11 is respectively formed in two side walls of the cuvette holding frame 7, the mounting slots 11 correspond to the mounting strips 9, and a protruding block 12 is fixedly mounted on the top surface of the cuvette holding frame 7, when in use, the cuvette is first placed in the cuvette holding frame 7, then the cuvette holding frame 7 is mounted in the cuvette holding groove 8, during the mounting process, the mounting strips 9 mounted in the cuvette holding groove 8 are inserted into the mounting slots 11 formed in the cuvette holding frame 7, if the cuvette is to be taken out, the cuvette storage rack 7 is drawn out from the cuvette placing groove 8 through the convex block 12.

As shown in fig. 5, in this embodiment, in order to rapidly move the sample to be detected to the same parallel line position of the optical path, two sides of the bottom surface of the groove of the sample chamber 5 are respectively and fixedly installed with a fixed plate 25, a T-shaped sliding groove 26 is opened on the top surface of the fixed plate 25, a positioning groove 27 is opened on the inner side wall of the fixed plate 25, two sets of symmetrical positioning blocks 14 are fixedly installed on the top surface of the sample storage rack 13, a connecting rod 18 is fixedly installed on the front end wall of the sample storage rack 13, the connecting rod 18 passes through the through hole 10, a pull ring 19 is fixedly installed on the front end of the connecting rod 18, symmetrical T-shaped sliding blocks 17 are fixedly installed on the bottom surface of the sample storage rack 13, the T-shaped sliding blocks 17 are movably installed in the T-shaped sliding grooves 26, a fixed block 20 is fixedly installed on the bottom surface of the sample storage rack 13, a through groove 21 is opened on the side wall of the fixed block 20, a compression spring 22 is movably installed in the through groove 21, clamping heads 24 are fixedly installed at two ends of a compression spring 22, retaining rings 23 are fixedly installed at notches at two ends of a through groove 21 respectively, the clamping heads 24 penetrate through the retaining rings 23, two groups of symmetrical positioning holes 16 are formed in the top surface of a cover plate 15, the positioning holes 16 correspond to positioning blocks 14, prepared samples to be detected and blank sample solutions are poured into cuvettes respectively, moisture and impurities outside the cuvettes are wiped by qualitative filter paper, the hair surfaces of the cuvettes are held by hands, the cuvettes containing the blank samples and the samples to be detected are placed in a sample storage rack 13 respectively, then the cover plate 15 is covered on the sample storage rack 13, in the process of the operation, the positioning blocks 14 installed on the sample storage rack 13 are inserted into the positioning holes 16 formed in the cover plate 15, then the cover 2 is covered on an instrument body 1, fingers are used for buckling a pull ring 19, and the sample storage rack 13 is pulled through a connecting rod 18 installed at the front end, in the course of this operation, the connecting rod 18 will be continuously moved out of the apparatus body 1 through the through hole 10, meanwhile, the T-shaped sliding block 17 installed on the bottom surface of the sample storage rack 13 will slide in the positioning slot 27 opened on the top surface of the fixed plate 25, and the compression spring 22 installed in the through slot 21 opened in the fixed block 20 will make continuous retraction movement, so that the chuck 24 installed on the front end thereof will abut against the inner wall of the fixed plate 25, when the sample storage rack 13 is moved to a certain extent, the compression spring 22 installed in the through groove 21 makes an extension movement, and the chuck 24 installed at the front end is pushed into a positioning groove 27 formed on the inner side wall of the fixing plate 25, at this time, the sample storage rack 13 is positioned and the sample storage rack 13 is stopped to be pulled, the sample to be tested stored in the sample storage rack 13 is kept at the same parallel line position with the light path.

While the invention has been described in detail with reference to the preferred embodiments thereof, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention, and it is intended that all matter contained in the above description or shown in the accompanying drawings shall be interpreted as illustrative and not in a limiting sense.

Claims (6)

1. The utility model provides a detection device of electrolytic copper foil chloridion which characterized in that: including instrument body (1), lid (2), display screen (3) and button (4), sample room (5) and cell standing groove (8) have been seted up on instrument body (1), the inslot of sample room (5) is equipped with slide positioning mechanism (6), slide positioning mechanism (6) are equipped with cell standing frame (7) including sample storage rack (13), apron (15), fixed block (20), compression spring (22), fender ring (23), dop (24) and fixed plate (25), two in the inslot of cell standing groove (8).

2. The apparatus for detecting chloride ions in an electrodeposited copper foil according to claim 1, wherein: the cell wall both sides of cell wall standing groove (8) are fixed mounting respectively has a set of symmetrical installation card strip (9), through-hole (10) have been seted up to the outer wall front end of instrument body (1), and through-hole (10) and sample room (5) communicate each other.

3. The apparatus for detecting chloride ions in an electrodeposited copper foil according to claim 2, characterized in that: vertical installation clamping groove (11) of a set of symmetry are seted up on the both sides lateral wall of cell storage rack (7) respectively, and installation clamping groove (11) and installation card strip (9) correspond each other, the top surface fixed mounting of cell storage rack (7) has protruding piece (12).

4. The apparatus for detecting chloride ions in an electrodeposited copper foil according to claim 3, wherein: the device comprises a sample chamber (5), wherein fixing plates (25) are fixedly mounted on two sides of the bottom surface of the sample chamber in the sample chamber (5) respectively, a T-shaped sliding groove (26) is formed in the top surface of each fixing plate (25), and a positioning groove (27) is formed in the inner side wall of each fixing plate (25).

5. The apparatus for detecting chloride ions in an electrodeposited copper foil according to claim 4, wherein: the utility model discloses a sample storage rack, including sample storage rack (13), top surface fixed mounting have locating piece (14) of two sets of symmetries, fixed mounting has connecting rod (18) on the front end wall of sample storage rack (13), and connecting rod (18) pass through-hole (10), the front end fixed mounting of connecting rod (18) has pull ring (19), the bottom surface fixed mounting of sample storage rack (13) has T type sliding block (17) of symmetry, T type sliding block (17) movable mounting is in T type sliding tray (26).

6. The apparatus for detecting chloride ions in an electrodeposited copper foil according to claim 5, wherein: the utility model discloses a sample storage rack, including sample storage rack (13), bottom surface fixed mounting has fixed block (20), logical groove (21) have been seted up on the lateral wall of fixed block (20), the inslot movable mounting who leads to groove (21) has compression spring (22), the both ends fixed mounting of compression spring (22) has dop (24), the both ends notch punishment that leads to groove (21) do not fixed mounting have and keep off ring (23), dop (24) pass and keep off ring (23), locating hole (16) of two sets of symmetries are seted up to the top surface of apron (15), and locating hole (16) and locating piece (14) correspond to each other.

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