CN219391157U - Electrolyte temperature detection device in storage battery formation process - Google Patents

Abstract

The utility model provides an electrolyte temperature detection device in a storage battery formation process. Belongs to the technical field of lead-acid storage battery formation. The method mainly solves the problems of undefined temperature and tracking of temperature change trend in the battery formation process. The main characteristics of the device are as follows: the device comprises a main computer control panel, a display screen, a connecting wire, a supporting frame, a temperature sensor fixing rod and a temperature sensor; the display screen is arranged on the control panel of the host computer and is electrically connected with the control panel of the host computer; the temperature sensor is arranged in the temperature sensor fixing rod, and the temperature sensor fixing rod is connected with the end part of the support frame; the temperature sensor is electrically connected with the control panel of the host computer through a connecting wire. The utility model has the characteristics of simple structure, capability of completing temperature tracking test in the battery formation process and being convenient for operators to know the temperature condition of the electrolyte, and is mainly used for monitoring the temperature of the electrolyte in the lead-acid storage battery formation process.

Description

Electrolyte temperature detection device in storage battery formation process

Technical Field

The utility model belongs to the technical field of lead-acid storage battery formation, and particularly relates to a device for detecting electrolyte temperature during lead-acid storage battery formation.

Background

The lead-acid storage battery formation procedure is a procedure of charging the battery with sulfuric acid, and respectively converting the positive plate into lead dioxide and the negative plate into velvet-shaped lead. In the formation process, the temperature of the electrolyte needs to be controlled within a certain range, so that the problem that the formation of the polar plate is poor due to the fact that the temperature is too high or too low is avoided, and the service life of the battery is influenced. The electrolyte temperature is preferably 30-60 ℃ during formation, and too low temperature can lead to the reduction of formation current density, insufficient formation and white spots generated on the polar plates; the temperature is too high, the gas precipitation potential of the anode and the cathode can be reduced, the gas precipitation is increased, the formation time is prolonged, meanwhile, the binding force between active substances and between grids and the active substances can be reduced, the service life of a polar plate can be reduced, the temperature is too high, the precipitation of partial substances in a baffle plate can be caused, and the problem of bubbling of mixed acid electrolyte is caused by the precipitation of a surfactant.

Because the battery formation time is longer and can reach 14-24 hours, when the temperature change is usually observed, the common thermometer is used for measurement, the temperature cannot be tracked in real time, the temperature is observed once at intervals, the data error is large, and the temperature change trend cannot be accurately mastered.

Disclosure of Invention

Aiming at the problem of insufficient control of electrolyte temperature in the formation process of a lead-acid storage battery in the background art, the utility model aims to provide a storage battery electrolyte temperature detection device which is used for detecting the electrolyte temperature change in the formation process, so that workers can know the real-time electrolyte temperature condition conveniently, and adjust the flow rate of circulating water according to the temperature condition in time, so that the electrolyte temperature meets the requirements, and the battery formation effect is ensured.

The technical scheme of the utility model is as follows: an electrolyte temperature detection device in a storage battery formation process is characterized in that: the device comprises a main computer control panel, a display screen, a connecting wire, a supporting frame, a temperature sensor fixing rod and a temperature sensor; the display screen is arranged on the control panel of the host computer and is electrically connected with the control panel of the host computer; the temperature sensor is fixed in the temperature sensor fixing rod, and the temperature sensor fixing rod can be placed in the fixing part for storage; the temperature sensor is electrically connected with the control panel of the host computer through a connecting wire.

The technical proposal of the utility model also comprises a shell base; the host computer control panel is fixedly arranged on the shell base.

The supporting frame in the technical proposal of the utility model is rotatably connected on the base of the shell.

The supporting frame in the technical proposal of the utility model is composed of two supporting arms which are rotatably connected; the end part of one supporting arm is rotatably connected with the shell base, and the end part of the other supporting arm is connected with the temperature sensor fixing rod.

The technical proposal of the utility model also comprises a fixing part; the fixed part is connected with the end part of the other supporting arm; the temperature sensor fixing rod is stored in the mounting through hole of the fixing part.

According to the technical scheme, the temperature sensor fixing rod is made of acid-resistant polytetrafluoroethylene materials, and the detachable acid-resistant rubber ring is sleeved on the temperature sensor fixing rod.

The technical proposal of the utility model also comprises a USB flash disk socket; the USB flash disk socket is arranged on a host computer control panel or a shell base.

The temperature sensor in the technical proposal of the utility model is a platinum thermal resistance sensor, and the temperature can be measured in a range: -20-220 ℃.

The connecting wire in the technical proposal of the utility model is a pluggable connecting wire, and is in pluggable electric connection with the temperature sensor and the control panel of the host computer.

The host computer control panel in the technical proposal of the utility model contains a thermal resistance module which can automatically process conversion and record temperature; the USB flash disk socket is arranged on a host computer control panel or a shell base; the temperature sensor is a platinum thermal resistance sensor, and the temperature can be measured in a range: -20-220 ℃; the connecting wire is a pluggable connecting wire, and is in pluggable electric connection with the temperature sensor and the control panel of the host computer.

The utility model adopts the electrolyte temperature detection device in the battery formation process, which consists of a main computer control panel, a display screen, a connecting wire, a supporting frame, a temperature sensor fixing rod and a temperature sensor, wherein the display screen is arranged on the main computer control panel and is electrically connected with the main computer control panel, the temperature sensor is arranged in the temperature sensor fixing rod, the temperature sensor fixing rod is connected with the end part of the supporting frame, and the temperature sensor is electrically connected with the main computer control panel through the connecting wire, so that when the lead-acid battery is formed, the temperature sensor fixing rod can be directly inserted into an acid adding hole on a battery big cover, the temperature sensor is positioned in acid liquor, an acid adding hole on the battery big cover is blocked, sulfuric acid volatilization is prevented, meanwhile, the temperature sensor fixing rod and a polar group are controlled to keep a certain distance, the temperature sensor is prevented from being damaged, the main computer control panel is started, the temperature of the electrolyte in the battery formation process can be monitored in real time, the temperature of the electrolyte is displayed on the display screen, a worker can know the temperature condition of the real-time electrolyte in time, the circulating water is convenient to adjust the temperature condition according to the temperature condition, the formation temperature is controlled to meet the formation temperature requirement, and the formation effect is improved.

The utility model has the characteristics of simple structure, capability of completing temperature tracking test in the battery formation process and being convenient for operators to know the temperature condition of the electrolyte, and is mainly used for monitoring the temperature of the electrolyte in the lead-acid storage battery formation process.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings required for the description of the embodiments will be briefly described below, and it is apparent that the drawings in the following description are only some embodiments of the present utility model, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural view of the present utility model.

In the figure: host computer control panel 1, display screen 2, USB flash disk socket 3, connecting wire 4, support frame 5, fixed part 6, acid-proof rubber ring 7, temperature sensor dead lever 8, temperature sensor 9.

Detailed Description

The following describes the technical solution of the present utility model (including the preferred technical solution) in further detail by means of fig. 1 and by way of illustrating some alternative embodiments of the present utility model. It will be apparent that the described embodiments are only some, but not all, embodiments of the utility model. 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 fall within the scope of the utility model.

As shown in fig. 1, the temperature detection device for the electrolyte of the storage battery, which is designed by the utility model, comprises a main computer control panel 1, a shell base, a display screen 2, a USB flash disk socket 3, a connecting wire 4, a supporting frame 5, a fixing part 6, an acid-resistant rubber ring 7, a temperature sensor fixing rod 8 and a temperature sensor 9.

The main computer control panel 1 is fixed on the base of the shell. The host computer control panel 1 is provided with a display screen 2, and the display screen 2 is used for displaying the real-time temperature. The main computer control panel 1 is a conventional main temperature control panel, and contains conventional temperature monitoring and processing programs, such as a thermal resistance module, and can automatically process conversion and record temperature. The host computer control panel 1 is provided with operation keys for setting a recording time range, data viewing, and export, and the like.

The display screen 2 is provided on the host computer control panel 1 and is electrically connected to the host computer control panel 1. The display 2 can display the temperature value and the temperature at a certain moment in a changing curve.

The USB flash disk socket 3 is arranged at the side part of the shell base and is electrically connected with the host computer control panel 1. The temperature data can automatically form a change curve through a system program in the control panel 1 of the host computer, and the data is exported through the USB flash disk.

The support 5 is composed of two support arms rotatably connected, wherein the end part of one support arm is rotatably connected with the side part of the base of the shell, and the end part of the other support arm is connected with the fixing part 6. The tightness degree of the rotatable connection between the two support arms and between the support arms and the shell base is proper, so that the two support arms can rotate relatively and can keep a corresponding state after rotating. The supporting frame 5 is used for supporting and fixing the temperature sensor fixing rod 8.

The fixing part 6 is rectangular block-shaped, and is provided with a through hole in the middle for storing the temperature sensor fixing rod 8.

The temperature sensor fixing rod 8 is made of polytetrafluoroethylene material, so that the temperature sensor 9 can be protected from being corroded by electrolyte. The detachable acid-resistant rubber ring 7 is sleeved on the temperature sensor fixing rod 8, so that an acid adding hole can be blocked on the battery large cover during actual formation, sulfuric acid volatilization is prevented, and meanwhile, the temperature sensor fixing rod 8 and the electrode group can be controlled to keep a certain distance, so that the electrode group and the sensor are prevented from being damaged. The acid-resistant rubber ring is detachable, so that the acid-resistant rubber ring is convenient to replace after being worn, and the use of the temperature sensor 9 is not affected.

The temperature sensor 9 is fixed inside the temperature sensor fixing rod 8. The temperature sensor 9 is a platinum thermal resistance sensor, and the measurable temperature range is: the temperature of 20 ℃ below zero to 220 ℃ below zero can completely meet the temperature change in the formation process.

The connecting wire 4 is a pluggable connecting wire and is in pluggable electric connection with the temperature sensor 9 and the host computer control panel 1. The temperature sensor 9 is replaceable after being damaged by adopting a pluggable connecting wire for connection.

It will be readily understood by those skilled in the art that the foregoing is merely illustrative of the preferred embodiments of the present utility model and that various modifications, combinations, substitutions, improvements, etc. may be made without departing from the spirit and principles of the utility model.

Claims (10)

1. An electrolyte temperature detection device in a storage battery formation process is characterized in that: the intelligent temperature sensor comprises a main computer control panel (1), a display screen (2), a connecting wire (4), a supporting frame (5), a temperature sensor fixing rod (8) and a temperature sensor (9); the display screen (2) is arranged on the main computer control panel (1) and is electrically connected with the main computer control panel (1); the temperature sensor (9) is fixed in the temperature sensor fixing rod (8), and the temperature sensor fixing rod (8) can be placed in the fixing part (6) for storage; the temperature sensor (9) is electrically connected with the host computer control panel (1) through a connecting wire (4).

2. The apparatus for detecting the electrolyte temperature in the formation process of a storage battery according to claim 1, wherein: the device also comprises a shell base; the main computer control panel (1) is fixedly arranged on the base of the shell.

3. The apparatus for detecting the electrolyte temperature in the formation process of a storage battery according to claim 2, wherein: the supporting frame (5) is rotatably connected to the base of the shell.

4. A battery formation process electrolyte temperature detection apparatus according to claim 3, wherein: the supporting frame (5) is composed of two supporting arms which are rotatably connected; the end part of one supporting arm is rotatably connected with the shell base, and the end part of the other supporting arm is connected with the fixing part (6).

5. The apparatus for detecting the electrolyte temperature in the formation process of a storage battery according to claim 4, wherein: also comprises a fixing part (6); the fixing part (6) is connected with the end part of the other supporting arm; the temperature sensor fixing rod (8) is stored in the mounting through hole of the fixing part (6).

6. The apparatus for detecting the electrolyte temperature in the formation process of a storage battery according to claim 5, wherein: the temperature sensor fixing rod (8) is made of acid-resistant polytetrafluoroethylene material, and a detachable acid-resistant rubber ring (7) is sleeved on the temperature sensor fixing rod (8).

7. The battery formation process electrolyte temperature detection apparatus according to any one of claims 1 to 6, wherein: the USB flash disk socket (3) is also included; the USB flash disk socket (3) is arranged on the host computer control panel (1) or the shell base.

8. The battery formation process electrolyte temperature detection apparatus according to any one of claims 1 to 6, wherein: the temperature sensor (9) is a platinum thermal resistance sensor, and can measure the temperature range: -20-220 ℃, and completely meets the use requirement.

9. The battery formation process electrolyte temperature detection apparatus according to any one of claims 1 to 6, wherein: the connecting wire (4) is a pluggable connecting wire, and is in pluggable electric connection with the temperature sensor (9) and the host computer control panel (1).

10. The battery formation process electrolyte temperature detection apparatus according to any one of claims 1 to 6, wherein: the host computer control panel (1) is internally provided with a thermal resistance module, and can automatically process, convert and record temperature; the USB flash disk socket (3) is arranged on the host computer control panel (1) or the shell base; the temperature sensor (9) is a thermal resistance sensor, and can measure the temperature range: -20-220 ℃; the connecting wire (4) is a pluggable connecting wire, and is in pluggable electric connection with the temperature sensor (9) and the host computer control panel (1).