KR19980043358U - Battery electrolyte specific gravity automatic adjustment device - Google Patents

Abstract

The present invention relates to a battery electrolyte specific gravity automatic adjustment device that automatically adjusts the specific gravity of the electrolyte in the battery so that the battery has the best power charging / discharging efficiency, in the battery according to the control signal from the control unit The electrolyte injection portion to be injected or blocked, the specific gravity detection unit for detecting whether the specific gravity of the electrolyte in the battery is an optimum value or the maximum limit value in the appropriate range, and the specific gravity of the electrolyte solution in the battery according to the detection signal by the specific gravity detection unit If the value is a control unit for controlling the electrolyte injection unit supply operation, and if the specific gravity of the electrolyte in the battery is an appropriate value by the control unit for controlling the blocking operation.

Description

Battery electrolyte specific gravity automatic adjustment device

The present invention relates to a battery, and more particularly to a battery electrolyte specific gravity automatic adjustment device for automatically adjusting the specific gravity of the electrolyte in the battery so that the battery has the best power charging / discharging efficiency.

Batteries are electrochemical devices that can accumulate and reuse DC power by applying chemical reactions. In general, an electrode plate is installed in a rectangular plastic case, and a certain amount of sulfuric acid or alkaline electrolyte is used for charging / discharging chemical reactions. It is injected into the inside, and the sulfuric acid battery uses a rare oil, and the alkaline battery uses a caustic solution of potassium hydroxide as an electrolyte. In addition, since the battery generates oxygen gas at the positive electrode and hydrogen gas at the negative electrode during charge / discharge, the specific gravity changes and the electrolyte level decreases, so that the electrolyte is frequently supplied so that the electrolyte level reaches an appropriate line (that is, a static specific gravity). shall.

That is, abnormality such as overcharging or overdischarging occurs intermittently due to negligence or carelessness during use of the battery.If this phenomenon persists without immediate action, the electrolyte is evaporated by boiling due to overheating. This changes and the electrolyte surface is lowered.

If such a specific gravity change and a liquid level deterioration state are not found by the inspector, and a long time elapses, the electrolyte depletion state increases with the specific gravity, which increases the electrical resistance and has a fatal effect on the power supply of the device, especially during a large current discharge.

In addition, a short circuit in the electrode plate may lead to a dangerous situation in which the battery may explode, and may also cause serious damage to the control equipment.

Thus, in order to prevent battery life and failure, the electrolyte should be maintained to have an appropriate weight. The proper weight of sulfuric acid battery is 1,280, its use range is 1,260 ~ 1,300, and the proper weight of alkaline battery is 1,200. Is 1,170-1,230.

Due to the characteristics of the battery, the specific gravity measurement is periodically performed, there is a problem in that it is cumbersome to supplement artificially when the specific gravity is lowered or the level is lowered, and there is a problem that accurate management is not made.

In addition, when replenishing the electrolyte, the electrolyte is poured into a narrow inlet by using a special container. Therefore, the surrounding area is inadvertently contaminated by the operator or the operator is injured. There was a problem of causing fatal burns.

The present invention has been made to solve the conventional problems as described above, the object is to continuously detect the specific gravity in the battery, and to supply or block the electrolyte to the battery according to the detected specific gravity of the battery electrolyte to maintain the proper specific gravity It is to provide specific gravity control device.

1 is a structural diagram showing a battery electrolyte specific gravity automatic adjustment device according to the present invention.

2 is an exploded perspective view of the battery electrolyte specific gravity automatic adjustment device shown in FIG.

3 is a cross-sectional view of the hydrometer and sensor in FIG.

4 is a circuit diagram showing the internal structure of the control unit.

* Description of the symbols for the main parts of the drawings *

1: Electrolyte specific gravity adjusting device 2: Control unit

3: hydrometer case 4: hydrometer

5: color mark 6A, 6B: sensor

9: electrolyte supply tank 10: solenoid valve

As a technical means for achieving the above object of the present invention, the present invention is a battery, the electrolyte injection unit for injecting or blocking the electrolyte solution in accordance with the control signal from the controller, and the specific gravity of the electrolyte in the battery The specific gravity detection unit for detecting whether the value is the proper value or the maximum limit in the proper range, and if the specific gravity of the electrolyte solution in the battery according to the detection signal by the detection signal by the specific gravity detection unit is the maximum limit value, the electrolyte injection unit controls the supply operation and the battery When the specific gravity of the electrolyte solution is an appropriate value, it is characterized by consisting of a control unit for controlling the electrolyte injection unit to block operation.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and operation of the present invention.

1 is a block diagram showing the specific gravity automatic adjustment device of the battery electrolyte according to the present invention, 1 is the specific gravity automatic adjustment device according to the present invention, 2 is the solenoid valve in accordance with the detection signals from the two color sensors (6A, 6B) 10 is a control unit for controlling the operation of the specific gravity is out of the appropriate range, 3 is a hexahedral shape is formed on one side opening hole through which the electrolyte flows from the battery 20 and the other side transparent material so that the inside is visible It is a specific gravity case consisting of (13), 4 is a hydrometer inserted into the specific gravity case (3) to move in accordance with the specific gravity, 5 is a color mark attached to any position of the hydrometer (4) to be a detection point of the sensor 6A is a color sensor installed at a position that detects the upper limit of the proper specific gravity range, 6B is a color sensor installed at a position that detects the static specific gravity, and 7 is a control unit that controls the output signal of the sensors 6A and 6B. 2) is a cable to be transmitted to, 8 is a cable for transmitting a control signal from the control unit 7 to the solenoid valve 10, 9 is an electrolyte supply tank containing the electrolyte to be injected when the electrolyte level of the battery 20 is reduced 10 is a solenoid valve for supplying / blocking the electrolyte supplied from the electrolyte supply tank 9 to the battery 20, and 11 is the solenoid valve 10 is installed, and the electrolyte supply tank 9 and the battery ( 20 is an electrolyte injection pipe connected to 12, and 12 is an electrolyte distribution formed on one surface of the battery 20 and one surface of the hydrometer case 3 so that electrolyte can be distributed between the battery 20 and the hydrometer case 3. Opening hole, 14 is a sensor base for fixing the two sensors (6A, 6B) to a predetermined position on the transparent surface 13 of the specific gravity case (3), 20 is a battery, 21A is on top of the battery 20 Electrolyte injection is formed and connected to the electrolyte injection pipe (11) 21B is an electrolyte inlet formed in the upper portion of the electrolyte supply tank 9.

FIG. 2 is an exploded perspective view showing the specific gravity automatic adjustment device 1 shown in FIG. 1, and the description of reference numerals shown in FIG. The electrolyte injection pipe 11 connected to the electrolyte supply tank 9 and provided with the solenoid valve 10 is coupled to the injection port 21A of the battery 20 by an injection port connecting lid 16, and the battery 20 And the electrolyte opening holes 12A and 12B formed in the hydrometer case 3 and the end portions are formed in a screw shape, and the two electrolyte opening holes 12A and 12B are connected by a screw coupling 12c. In the present embodiment, after forming the electrolyte opening hole (12A) in the existing battery, it is connected to the hydrometer case (3) by the screw coupling (12c), but the case and the hydrometer case (3) of the battery 20 ) Is preferably formed integrally.

In addition, a sensor base 14 having a plurality of holes 15 for installing a sensor is integrally formed on the transparent surface of the hydrometer case 3, and the two sensors 6A and 6B are connected to the sensor installation hole ( 15).

FIG. 3 is a cross-sectional view showing the specific gravity detection unit in detail, and the electrolytic solution 31 is filled in the hydrometer case 3 at the same height as the electrolyte solution in the battery 20, and the guide ring is fixedly attached to the inside of the hydrometer case 3. 30, the hydrometer 4 is built in, the color mark 5 is attached to a predetermined position of the hydrometer 4, and three color sensors 6A, 6B are provided on the transparent surface of the hydrometer case 3. Each is attached to have a predetermined height.

4 is a diagram showing the circuit configuration of the control unit according to the present invention. The switch 6A ', which is in the cut-off state and is in a conductive state by the detection signal from the first sensor 6A, is connected to the epicenter. The first relay R1 is connected to the other end of the switch 6A ', and the switch 6B' which is always in a conductive state and is cut off by a detection signal from the second sensor 6B is connected to the epicenter. A second relay R2 is connected to the other end of the switch 6B ', and the A contact R1' of the first relay R1 and the A contact R2 'of the second relay R2 are in series. Is connected to a third relay R3, and a normal notification lamp L2 is connected to the contact A2 of the second relay R2, and the contact A of the third relay R3 is connected to the third relay R3. (R3 ') is connected in parallel to the contact A (R1') of the first relay (R1), the solenoid valve 10 and the buzzer (B) to the contact A (R3 ') of the third relay (R3) And warning lamps (L1) connected in parallel The.

Next, the effect | action by the structure mentioned above is demonstrated.

In FIG. 1, the battery 20 and the hydrometer case 3 are connected through the electrolyte distribution opening hole 12 so that the electrolyte solution in the battery 20 and the electrolyte solution in the hydrometer case 3 are always filled to the same height. Therefore, the hydrometer 4 in the hydrometer case 3 detects the specific gravity of the electrolyte in the battery 20. That is, the vertical movement is performed according to the specific gravity of the electrolyte in the battery 20, when the specific gravity of the electrolyte is low is lowered, and the higher the specific gravity of the electrolyte is up.

The specific gravity detection operation by the hydrometer 4 will be described with reference to FIG.

The hydrometer 4 is inserted into the ring of the guide ring 30 and embedded in the hydrometer case 3. The inner diameter of the guide ring 30 is formed slightly larger than the diameter of the glass long part of the hydrometer 4, the hydrometer 4 can freely move up and down within the guide ring 30, the guide ring ( 30 is for preventing the hydrometer 4 from moving left and right by external vibration.

According to the above, the hydrometer 4 stably moves up and down in accordance with the specific gravity of the electrolyte 31, thereby changing the position of the color mark 5 attached to the predetermined position of the hydrometer 4. The two sensors 6A and 6B are installed at predetermined positions, respectively, to detect the color marks 5 located at the heights at which the sensors 6A and 6B are installed. The height at which the sensor 6A is installed is a height at which the color mark 5 can be detected when the electrolyte 31 has a maximum limit of an appropriate range of specific gravity, and the position at which the sensor 6B is installed is the electrolyte 31. ) Is a height capable of detecting the color mark 5 attached to the hydrometer 5 when it has an appropriate specific gravity value.

Therefore, when the specific gravity of the electrolyte solution 31 reaches an appropriate value, the sensor 6B detects it and a detection signal is output from the sensor 6B. When the specific gravity of the electrolyte solution 31 reaches the maximum limit of an appropriate range, the sensor ( 6A) detects this, and a detection signal is output from the sensor 6A.

The detection signals output from the two sensors 6A and 6B are input to the controller 2, and the controller 2 checks the detection signals of the two sensors 6A and 6B to perform the opening / closing operation of the electrolyte 31. To control. That is, when a detection signal that detects a color mark is output from the sensor 6A (that is, when the specific gravity of the electrolyte in the battery 20 exceeds the appropriate range), the solenoid valve 10 is controlled to expand and operate. When the electrolyte from the supply tank 9 is injected into the battery 20 through the electrolyte supply pipe 11, and a detection signal that detects a color mark from the sensor 6B is output (that is, the battery 20) When the specific gravity of the electrolyte solution reaches an appropriate value), the solenoid valve 10 is shut off to block the electrolyte solution injected from the electrolyte supply tank 9. When the detection signal is applied from the sensor 6A, the control unit 2 operates an internal alarm device (for example, an alarm lamp or a buzzer), and the operator reaches a dangerous value of the electrolyte concentration in the battery 20. Inform them.

The operation of the controller 2 will be described in more detail with reference to the circuit diagram shown in FIG.

In FIG. 3, when the battery 20 malfunctions and the specific gravity of the electrolyte 31 becomes high, the hydrometer 5 moves upward, and the color mark 5 attached to the hydrometer 5 also moves upward simultaneously. Is moved. In this way, when the specific gravity is gradually increased and the color mark 5 is raised to the position of the sensor 6A, when the sensor 6A detects it, in FIG. 4, the switch 6A 'is brought into a conducting state and the first state is obtained. The power is applied to the relay R1 so that the first relay R1 is excited, so that the contact A1 of the first relay R1 is in a conductive state, and the second relay R2 is always excited. ), The contact A2 of the second relay R2 is in a conductive state, so that power is applied to the third relay R3 and excited. Accordingly, while the A contact R3 'of the third relay R3 is in a conducting state, power is applied to the solenoid valve 10 connected to the A contact R3', and the solenoid valve 10 is in a deployed state. The electrolyte is injected, the power is applied to the buzzer B and the alarm lamp L1, the buzzer sound is output from the buzzer B, and the alarm lamp L1 is turned on. As a result, the operator can see that the specific gravity of the electrolyte in the battery 20 is too high.

When the electrolyte is injected into the battery 20 by the development of the solenoid valve 10, the specific gravity of the electrolyte 31 is gradually lowered, and the hydrometer 4 moves downward, and the color mark 5 attached thereto is attached. The position of is also getting lower. Then, when the position of the color mark 5 reaches a position parallel to the second sensor 6B, the second sensor 6B suddenly detects this, outputs a detection signal, and the switch 6B is always in a conductive state. ') Becomes a cutoff state, and thus the power applied to the second relay R2 is cut off. Therefore, the contact A2 of the second relay R2 is in a normal state, and thus the power supply to the third relay R3 is cut off. As a result, the buzzer B and the warning lamp L1 stop operation, and power is applied to the normal notification lamp L2 connected to the contact A2 of the excited second relay R2 and turned on. . Thus, the operator can know that the specific gravity of the electrolyte in the battery 20 is an appropriate value.

As such, the present invention constantly checks the specific gravity of the electrolyte in the battery and automatically injects or blocks the electrolyte so that the specific gravity thereof is appropriate, thereby eliminating the need for the operator to check the specific gravity as often as in the prior art, thereby providing convenience and safety to the operator. In addition, since the electrolyte in the battery can always maintain a proper state, it has an excellent effect of extending the life of the battery, reducing the failure rate and maintaining the battery in an optimal state.

Claims (5)

In the battery, An electrolyte injection unit for injecting or blocking electrolyte into the battery according to a control signal from a controller; A specific gravity detection unit for detecting whether the specific gravity of the electrolyte solution in the battery is an optimum value or a maximum limit value in an appropriate range; And a control unit for controlling the electrolyte injection unit to supply when the specific gravity of the electrolyte in the battery is the maximum limit value according to the detection signal of the specific gravity detection unit, and to block the electrolyte injection unit when the electrolyte concentration in the battery is an appropriate value. Battery electrolyte specific gravity automatic adjustment device. The method of claim 1, The electrolyte injection unit One end is coupled to the electrolyte supply tank 9 containing the electrolyte to be injected into the battery 20, and the electrolyte supply tank 9, and the other end is coupled to the inlet 21A of the battery 20. The battery is characterized in that it is formed of an electrolytic valve (11) connected by the 16 and the solenoid valve (10) installed in the middle of the electrolyte injection pipe 11 to block or conduct the electrolyte injection pipe (11) Electrolyte specific gravity automatic adjustment device. The method of claim 1, The specific gravity detection unit The electrolyte distribution opening hole 12A formed on one surface of the battery 20 and the electrolyte distribution opening hole 12B formed on one surface of the hydrometer case 3 are coupled by the coupling 12C, and the inside thereof is formed of an empty cube. A hydrometer case (3), one surface of which is made of a transparent material, A hydrometer 4 which is fixed to the left and right by a guide ring 30 attached to the inside of the specific gravity case 3 and attaches a color mark 5 at a predetermined position to vertically move according to the specific gravity of the electrolyte; The color mark 5 can be sensed when the specific gravity of the electrolyte solution 31 is appropriate by the sensor installation holes 15 formed in the sensor base 14 integrally formed on the transparent surface of the specific gravity case 3. When the specific gravity of the height and the electrolyte 31 is the upper limit value of the appropriate range, it consists of an appropriate specific gravity sensor (6B) and the limit specific gravity sensor (6A) installed at a height capable of sensing the color mark (5) Battery electrolyte specific gravity automatic adjustment device. The method of claim 1, The control unit The appropriate specific gravity detection sensor is in a conduction state when detecting the color mark, and connects the switch 6A 'to a power supply terminal, and connects the first relay R1 to the other end of the switch 6A', and the limit specific gravity detection. When the sensor detects the color mark, the switch 6B ', which is in a blocking state, is connected to a power supply terminal, a second relay R1 is connected to the other end of the switch 6B', and the first relay R1 The A contact R1 'and the A contact R2' of the second relay R2 are connected in series, the third relay R3 is connected to one end thereof, and the A contact of the third relay R3 ( R3 ') is connected in parallel with the contact A of the first relay R1', and the solenoid valve 10 and the buzzer B are connected to one end of the contact A3 of the third relay R3. And a warning lamp L1 is connected in parallel, and a normal notification lamp L2 is connected to the contact point R2 'of the second relay R2. The method according to claim 1, wherein The battery (20) and the hydrometer case (3) is a battery electrolyte specific gravity automatic adjustment device, characterized in that formed integrally.