RU40810U1 - COMPLEX OF EQUIPMENT FOR TESTING BATTERIES OF REchargeable CHEMICAL CURRENT SOURCES - Google Patents

Abstract

The working body for tillage is structurally symmetrical with respect to the attachment point, multi-blade with a self-sharpening effect and an adjustable angle of inclination of the working surface to the horizon. The effect of self-sharpening is enhanced by setting a variable cross-section in the region of the blade with ribs parallel to the direction of motion, having hard-facing surfacing along the peaks, or having a hard-alloy coating, which leads to different abrasion wear rates, and the formation of stress-reducing stresses on the blade edges that reduce traction resistance of the working body. A symmetrical, multi-blade organ allows you to enhance the effect of self-sharpening due to periodic forced rotation, and when one or more blades are torn off, a blow in rocky soil allows you to partially maintain efficiency by turning it 180 °. The method of fastening the working body allows you to change the angle of inclination of the working surface to the horizon due to the adjusting washers on one of the mounting bolts depending on the condition and composition of the soil environment.

Description

The utility model relates to the field of production of chemical current sources and can be used for acceptance and resource tests of batteries of rechargeable chemical current sources.

The closest set of essential features to this utility model is a system for diagnosing a lead battery connected to a charger and load. The system contains voltage, current and battery temperature sensors, density and electrolyte level sensors in individual battery batteries, a unit for processing the results of measurements of controlled parameters, a measuring unit based on the ADC, a controlled amplifier and a switch. (USSR patent No. 1783479 A 1, class G 05 B 23 / 02.1992)

The disadvantage of this known set of equipment for testing a battery is a tough program for testing a battery.

The objective of the utility model is to create a set of equipment for conducting complex tests of batteries of rechargeable chemical current sources, the program of which can be set and changed by the user in real time over a wide range.

The specified technical result is achieved by the fact that in the known set of equipment for testing batteries of rechargeable chemical current sources, which contains sensors of the electrophysical parameters of the battery and single chemical current sources, a unit for recording signals of electrophysical sensors, a unit for processing measurement results and generating control signals, a power unit that provides the specified modes of discharge and battery charge of rechargeable chemical current sources, as a processing unit of the results and measurements and generating control signals used personal electronic computer (PC). Using a PC as a unit for processing measurement results and generating control signals allows testing batteries of rechargeable chemical current sources in complex multi-stage modes, the parameters of which can be entered by the operator both before and during the test, since modern PCs have high computing resources and speed. The proposed set of equipment can be used for long life tests conducted according to cyclic programs without the direct participation of the operator.

It is advisable that the set of equipment for testing batteries of rechargeable chemical current sources contains a battery protection unit for chemical rechargeable current sources that generates light and sound alarms and disconnects the battery of rechargeable chemical current sources from the power unit when the PC fails (freezes) or the power supply voltage fails block or PC Protection block, it is advisable to perform on the basis of a microprocessor. The introduction of a protection unit into the complex of equipment allows to increase the reliability of the complex and protect the battery of chemical rechargeable current sources from overcharging or overdischarge during PC malfunctions, and also eliminates the possibility of battery discharge through the power unit circuit in the event of a power failure.

It is advisable that, in a set of equipment for testing batteries of rechargeable chemical current sources, the power unit is controlled through an interface unit that converts PC commands into control signals of the required level and shape. The interface unit allows you to simplify the hardware of the power unit using analog or discrete (logical) signals to control it.

It is advisable that in the complex of equipment for testing batteries of rechargeable chemical current sources the power unit contains at least one microprocessor, and the power unit is controlled through one or more standard PC ports. Using standard PC ports to control the power unit simplifies the creation of work programs when developing a set of equipment.

It is advisable that, in the complex of equipment for testing batteries of rechargeable chemical current sources, the unit for recording signals of electrophysical sensors be made in the form of a set of electronic devices (electronic modules) designed to register signals from several of the same type of electrophysical sensors and installed in a single crate (case) that provides power supply and communication with a PC of electronic devices (modules) installed in it. The use of subracks simplifies the hardware of the unit for recording signals of electrophysical sensors.

It is advisable that, in the complex of equipment for testing batteries of rechargeable chemical current sources, the unit for recording signals of electrophysical sensors was made in the form of separate electronic units designed to register signals from several electrophysical sensors of the same type and connected to a personal computer via a standard interface. It is advisable that the signal recording blocks of the electrophysical sensors and the power block are connected to the PC via a USB bus. Such a construction of a signal recording unit for electrophysical sensors increases the reliability of the entire system and simplifies the creation of work programs when developing a set of equipment.

The analysis of the prior art showed that the claimed combination of essential features set forth in the utility model formula is unknown. This allows us to conclude that it meets the criterion of "novelty."

The essence of the utility model is illustrated by a drawing and a description of the principle of operation.

Figure 1 presents a functional diagram of a set of equipment for testing a battery of sealed nickel-cadmium batteries.

The equipment complex consists of a personal computer 1, a rack device 2, in which a unit for recording signals of electrophysical sensors 3 and an interface unit 4, electrophysical sensors 5, a power unit 6 and a battery protection unit 7 are installed.

The complex works as follows. Electrophysical sensors 5: voltage and temperature sensors of the battery case, voltage sensors and threshold pressure sensors of single batteries are installed in the battery. The battery current sensor is installed in the power unit 6. The signals from the electrophysical sensors are received and processed in the signal recording unit of the electrophysical sensors 3, which is installed in the subrack. The sub-rack device provides power to the recording unit 3, as well as transmitting the information received from the registration unit to the PC 1 through its LPT port. The power unit 6 provides the PC-specific charge or discharge modes of the battery. The operating mode of the power unit 6 is set by the PC via two channels: directly through the COM port and through the interface unit 4 installed in the sub-rack 2. The PC 1 is controlled by the microprocessor-based battery protection unit 7, which constantly exchanges signals with the PC. When the PC freezes up, the PC or the sub-rack device malfunctions, the corresponding signals cease to enter the microprocessor of the battery protection unit. In this case, the microprocessor generates light and sound alarms and disconnects the battery from the power unit. The battery test program is entered by the operator into the PC using the keyboard and display. All registered parameters are reflected on the PC display in real time.

The above description of the operation of the inventive equipment complex shows that this device can be implemented in practice. Therefore, the claimed utility model meets the criterion of "industrial applicability".

Claims (8)

1. A set of equipment for testing batteries of rechargeable chemical current sources, containing sensors of the electrophysical parameters of the battery and single rechargeable chemical current sources, a unit for recording signals of electrophysical sensors, a unit for processing measurement results and generating control signals, a power unit that provides the specified discharge and charge conditions for chemical batteries current sources, characterized in that as a unit for processing measurement results and generating control signals used personal electronic computer (PC). 2. A set of equipment for testing batteries of rechargeable chemical current sources according to claim 1, characterized in that it contains a battery protection unit for chemical rechargeable current sources that generates light and sound alarms and disconnects the battery of rechargeable chemical current sources from the power unit in the event of a malfunction ( freezing) PC or power failure of the power unit or PC. 3. A set of equipment for testing batteries of rechargeable chemical current sources according to claim 2, characterized in that the protection unit is based on a microprocessor. 4. A set of equipment for testing batteries of rechargeable chemical current sources according to any one of claims 1 to 3, characterized in that the power unit is controlled through an interface unit that converts PC commands into control signals of the required level and shape. 5. A set of equipment for testing batteries of rechargeable chemical current sources according to any one of claims 1 to 3, characterized in that the power unit contains at least one microprocessor, and the power unit is controlled through one or more standard PC ports. 6. A set of equipment for testing batteries of rechargeable chemical current sources according to any one of claims 1 to 3, characterized in that the unit for recording signals of electrophysical sensors is made in the form of a set of electronic devices (electronic modules) designed to register signals from several of the same type of electrophysical sensors and installed in a single crate (case), which provides power supply and communication with a PC of electronic devices (modules) installed in it. 7. A set of equipment for testing batteries of rechargeable chemical current sources according to any one of claims 1 to 3, characterized in that the unit for recording signals of electrophysical sensors is made in the form of separate electronic units designed to register signals from several of the same type of electrophysical sensors and connected to a PC according to standard interface. 8. A set of equipment for testing batteries of rechargeable chemical current sources according to claim 7, characterized in that the signal recording units of the electrophysical sensors and the power unit are connected to the PC via a USB bus.