CN219319308U - Microcomputer double-side electrolysis thickness gauge - Google Patents

Abstract

A microcomputer double-sided electrolytic thickness gauge comprising: the device comprises a base, two side baffles, a transverse bracket, a spiral fastener, an anode clamp, a power supply, a test microcomputer, a cathode clamp, a stirring air pipe, an electrolyte drop inlet, an L-shaped electrolytic cup, a circular sucker and an electrolytic cell; the function of measuring the thickness of the plating layer on one side of the plating sample and simultaneously measuring the thickness of the plating layer on both sides of the sample can be realized. The adoption of the double electrolytic cells effectively solves the problem of simultaneously measuring the thickness of the plating layers on the two sides of the sample; the structure of transversely sliding left and right and vertically holding the workpiece breaks through the structure of the traditional up-down sliding electrolytic cell, and an L-shaped electrolytic cup closed passage is adopted, so that the electrolyte is prevented from leaking; the microcomputer displays the measured data, so that the method is simple and convenient, and more importantly, the data is long in storage time, complete and not easy to lose.

Description

Microcomputer double-side electrolysis thickness gauge

Technical Field

The utility model relates to a laboratory instrument for measuring the thickness of a plating layer, in particular to an instrument which can simultaneously measure the thickness of a plating layer on two sides and read data by using a microcomputer.

Background

The microcomputer double-side electrolytic thickness meter is an instrument for measuring the thickness of a plating layer, and the plating layer thickness is measured by the potential change and the required time when the anode dissolves the plating layer to reach the substrate. The plating is usually double-sided plating of metal sheets, the plating thickness of only one side can be measured by adopting a traditional electrolytic thickness gauge, if the two sides are measured, the plating sheets are turned over and clamped again, electrolyte is dripped, the experimental operation is complicated, and the efficiency is low; the force used for manually clamping the sample is random, and the surface of the sample is easy to damage. In order to enable experiment staff to efficiently complete experiment operation, simultaneously measure the thickness of a double-sided plating layer and avoid damaging a sample, aiming at the technical problem to be solved by the embodiment of the utility model, a method for simultaneously measuring the thickness of the sample at two sides is adopted, and the pressure born by the surface of the sample is monitored in real time by utilizing a pressure sensing air pipe, so that the microcomputer double-sided electrolysis thickness gauge is provided.

Disclosure of Invention

The utility model aims to solve the problem that the plating thickness of two sides of a plated part with plating layers on two sides needs to be measured one by one, and designs a microcomputer double-side electrolysis thickness meter which can realize simultaneous measurement of the plating layers on the two sides and rapidly and accurately read data by utilizing a microcomputer.

The technical scheme of the utility model is as follows: a microcomputer double-sided electrolytic thickness gauge comprising: the device comprises a base, two side baffles, a transverse bracket, a spiral fastener, an anode clamp, a power supply, a test microcomputer, a cathode clamp, a stirring air pipe, an electrolyte drop inlet, an L-shaped electrolytic cup, a circular sucker and an electrolytic cell; the method is characterized in that: the base is positioned on the horizontal table top; the test microcomputer is connected with the power supply wire; the baffles on two sides are fixedly connected with the base; the transverse bracket is fixedly connected with the baffles at the two sides; the two electrolytic cells are connected on the transverse bracket in a sliding way through two spiral fasteners; the circular sucker is fixedly connected with the L-shaped electrolytic cup; the L-shaped electrolytic cup is movably connected with the stirring air pipe; the stirring air pipe is connected with the test microcomputer through a wire; the test microcomputer is connected with the anode clamp wire; the cathode clamp is connected with the microcomputer lead.

The microcomputer is a computer with small occupied area, is convenient and sensitive to operate, provides an operable platform for DJH-G electrolytic thickness gauge software, and ensures the normal operation of the DJH-G electrolytic thickness gauge software.

Preferably, the microcomputer mainly utilizes DJH-G electrolytic thickness gauge software to measure the thickness of the plating layer under the condition of ensuring that the DJH-G electrolytic thickness gauge software runs normally, and parameters such as the substrate, the layer number, the plating seed, the maximum thickness and the like of the sample can be adjusted by the software, so that the thickness of the plating layer of the sample is finally tested.

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

the device is mainly used for measuring the thickness of the plating layer, and can be used for measuring the thickness of the plating layer on one side of the plating sample and simultaneously measuring the thickness of the plating layer on two sides of the sample. The adoption of the double electrolytic cells effectively solves the problem of simultaneously measuring the thickness of the plating layers on the two sides of the sample; the structure of transversely sliding left and right and vertically holding the workpiece breaks through the structure of the traditional up-down sliding electrolytic cell, and an L-shaped electrolytic cup closed passage is adopted, so that the electrolyte is prevented from leaking; the microcomputer displays the measured data, so that the method is simple and convenient, and more importantly, the data is long in storage time, complete and not easy to lose.

Drawings

Fig. 1 is a schematic diagram of the structure of the present utility model.

In fig. 1: 1. the device comprises a base, two side baffles, 3, a transverse support, 4, a spiral fastener, 5, an anode clamp, 6, a power supply, 7, a test microcomputer, 8, a cathode clamp, 9, a stirring air pipe, 10, an electrolyte drop inlet, 11, an L-shaped electrolytic cup, 12, a circular sucker, 13 and an electrolytic cell.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model. A microcomputer double-sided electrolytic thickness gauge comprising: the device comprises a base, two side baffles, a transverse bracket, a spiral fastener, an anode clamp, a power supply, a test microcomputer, a cathode clamp, a stirring air pipe, an electrolyte drop inlet, an L-shaped electrolytic cup, a circular sucker and an electrolytic cell; the method is characterized in that: the base is positioned on the horizontal table top; the test microcomputer is connected with the power supply wire; the baffles on two sides are fixedly connected with the base; the transverse bracket is fixedly connected with the baffles at the two sides; the two electrolytic cells are connected on the transverse bracket in a sliding way through two spiral fasteners; the circular sucker is fixedly connected with the L-shaped electrolytic cup; the L-shaped electrolytic cup is movably connected with the stirring air pipe; the stirring air pipe is connected with the test microcomputer through a wire; the test microcomputer is connected with the anode clamp wire; the cathode clamp is connected with the microcomputer lead.

The microcomputer model is Vostro 3590.

The microcomputer Vostro 3590 mentioned in the present utility model can be obtained in market or private order.

The base is positioned on the horizontal table top; the test microcomputer is connected with the power supply wire; the baffles on two sides are fixedly connected with the base; the transverse bracket is fixedly connected with the baffles at the two sides; the two electrolytic cells are connected on the transverse bracket in a sliding way through two spiral fasteners; the circular sucker is fixedly connected with the L-shaped electrolytic cup; the L-shaped electrolytic cup is movably connected with the stirring air pipe; the stirring air pipe is connected with the test microcomputer through a wire; the test microcomputer is connected with the anode clamp wire; the cathode clamp is connected with the microcomputer lead.

When the microcomputer double-side electrolysis thickness gauge is used, after the surface of a workpiece to be measured is cleaned, placing the processed sample to be measured between two electrolytic cells, and adjusting the left and right positions of the two electrolytic cells to enable the electrolytic cells to be close to the workpiece to be measured; two spiral fasteners are slowly regulated by two hands, and an electrolytic cell device is fixed, so that round suckers of electrolytic cells at two sides are tightly closed with a workpiece sample at the same time, and electrolyte is prevented from leaking out; two cathode clamps are respectively inserted into two electrolytic cups, the anode clamps are clamped on a sample to be tested, and then a proper amount of electrolyte is simultaneously dripped into two electrolyte drop inlets respectively above. After the operation is finished, a power supply and a microcomputer are turned on, all the equipment is in a state to be operated, then DJH-G electrolytic thickness gauge software is turned on through the microcomputer, the selection of a substrate, the number of layers, the plating of the seeds, the setting of the maximum thickness, the selection of the size of an area, the setting of the lot number of a workpiece, the input of parameters such as the name of a test person and the like are carried out, and the measurement is carried out. The measured data are transmitted to the microcomputer through the lead wires, and experimental data are displayed on the microcomputer. After the measurement is finished, the electrolytic cell is cleaned by a dropper for fine waste liquid.

It should be further noted that the device is mainly used for measuring the thickness of the plating layer, and can be used for measuring the thickness of the plating layer on one side of the plating sample and simultaneously measuring the thickness of the plating layer on two sides of the sample. The adoption of the double electrolytic cells effectively solves the problem of simultaneously measuring the thickness of the plating layers on the two sides of the sample; the structure of the traditional up-and-down sliding electrolytic cell is broken, a structure of transversely sliding left and right and vertically holding a workpiece is adopted, and an L-shaped electrolytic cup closed passage is adopted, so that the electrolyte is prevented from leaking out; the microcomputer displays the measured data, so that the method is simple and convenient, and more importantly, the data is long in storage time, complete and not easy to lose.

The preferred embodiments of the utility model disclosed above are intended only to assist in the explanation of the utility model. The preferred embodiments are not exhaustive or to limit the utility model to the precise form disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the utility model and the practical application, to thereby enable others skilled in the art to best understand and utilize the utility model. The utility model is limited only by the claims and the full scope and equivalents thereof.

Claims (1)

1. A microcomputer double-sided electrolytic thickness gauge comprising: the device comprises a base, two side baffles, a transverse bracket, a spiral fastener, an anode clamp, a power supply, a test microcomputer, a cathode clamp, a stirring air pipe, an electrolyte drop inlet, an L-shaped electrolytic cup, a circular sucker and an electrolytic cell; the method is characterized in that: the base is positioned on on the horizontal table top; the test microcomputer is connected with the power supply wire; two-side baffle the base is fixedly connected; the transverse bracket is fixedly connected with the baffles at the two sides; the two electrolytic cells are connected on the transverse bracket in a sliding way through two spiral fasteners; the circular sucker is fixedly connected with the L-shaped electrolytic cup; the L-shaped electrolytic cup is movably connected with the stirring air pipe; the stirring air pipe is connected with the test microcomputer through a wire; the test microcomputer is connected with the anode clamp wire; the cathode clamp is connected with the microcomputer lead.

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