RU91482U1 - DEVICE FOR MULTI-POST CHARGING OF BATTERIES - Google Patents

Abstract

A device for multi-post charging of batteries containing a current source to which charging posts are connected in series, each of which is equipped with a bypass contactor, a battery connector configured to mechanically open the bypass contactor, a diode and a current sensor connected in series with the battery connector, a voltage resistor divider, connected in parallel to the battery connector, the first switch bypass bypass, and the second switch ohm, partially shunting the arm of the resistor divider, while the control input of the first switch through a threshold element is connected to the output of the resistor voltage divider, and the control input of the second switch is connected to the output of the current sensor.

Description

Technical field

The proposal relates to electrical engineering and can be applied in devices for the mass charging of batteries used in automobiles, backup power sources, electric cars, as well as in small electric vehicles (electric bicycles, electric moped, etc.).

State of the art

A device for multi-post charging batteries containing a charging current source, to which individual charging posts are connected in series, each of which contains a battery connector, a diode connected in series with the connector, and a bypass contactor made in the form of a thyristor with a resistor voltage divider in the control circuit, triggered when the specified voltage is reached on the rechargeable battery [1]. The device [1] uses a single current source to power all charging stations and allows each charging station to be taken out of the circuit of the common charging current individually after charging its battery. The disadvantage of this device is the inconvenience of operation due to the need to interrupt the common charging current circuit when charging another battery.

A device for charging electric batteries containing a charging current source is also known, to which individual charging posts are connected in series, each of which is equipped with a bypass contactor, a rechargeable battery connector configured to mechanically open the bypass contactor, and a diode connected in series with the indicated connector. [2]. This device provides both output and charging for the next battery without interrupting the overall charging current circuit.

A common drawback of devices [1] and [2] for multi-charging batteries from a common charging current source is the inability to accelerate charging by using individual battery charging modes depending on the voltage on it, for example, charging mode with an asymmetric (reverse) charging current [3-5 ].

A device for multi-post charging batteries containing individual sources of charging current for powering each charging station, made in the form of a thyristor converter, and a common multi-channel control system [6]. With the appropriate implementation of the multi-channel control system, the device [6] allows for charging, battery output and control of its charging current at each post separately.

The disadvantage of the device [6] is the high cost of equipment due to the presence of a separate regulated current source at each charging station.

Utility model creature disclosure

The objective of the utility model is to eliminate these disadvantages of known devices.

The technical result of the utility model is the possibility of multi-post charging of batteries from one common current source with provision for charging, output of a charged battery and control of the charging current at each post separately without interrupting the circuit of the common charging current.

The object of the utility model is a device for multi-charging batteries, containing a current source, to which charging posts are connected in series, each of which is equipped with a bypass contactor, a battery connector configured to mechanically open the bypass contactor, a diode and a current sensor connected in series with the battery connector, a resistor voltage divider connected in parallel to the battery connector, the first switch bypass shunt ny contactor and a second switch, the shoulder part shunt resistor divider, wherein the control input of the first switch through a threshold element connected to the output resistor of the voltage divider and the control input of the second switch is connected to the output of the current sensor.

This ensures that the specified technical result.

Utility Model Implementation

Figure 1 presents an example diagram of a device, and figure 2 is a timing diagram explaining its operation.

Figure 1 shows the current source 1, to which the charging posts 2 are connected in series. Each of the posts 2 is equipped with a bypass contactor 3 and a rechargeable battery connector 4, configured to mechanically open the contactor 3.

In addition, each charging station is equipped with:

- diode 5 and current sensor 6, connected in series with connector 4;

- resistor voltage divider 7 connected in parallel to the connector 4;

- the first switch 8, bypassing the contactor 3;

- the second switch 9, partially shunting the shoulder of the divider 7.

The control input 10 of the switch 8 through the threshold element 11 is connected to the output 12 of the divider 7, and the control input 13 of the switch 9 is connected to the output of the sensor 6. The connector 4 is made with the possibility of mechanical opening of the contactor 3 when connected to the charging station. Such mechanical blocking can be performed, for example, as described in [2]. According to [2]. the connector 4 is made in the form of a plug with an insulated pin designed to connect the battery 14, and the contactor 3 is in the form of a socket with a spring-loaded conductive element bypassing (bypassing) the corresponding charging post in the common charging current circuit.

The device operates as follows.

While the connector 4 is not connected to the post 2, the current from the source 1 flows, bypassing the post, through the contactor 3. The sensor 6 detects the absence of current and gives a signal to the control input 13 of the switch 9, which supports the open state of the switch 9.

The battery 14, intended for charging, is connected to the connector 4 (plug), which is then inserted into the socket of the contactor 3. In this case, the contactor 3 opens due to the mechanical locking described above (the insulated pin of the connector 4 mechanically deflects the spring-loaded conductive element of the contactor 3).

The current from the source 1 flows through the diode 5, sensor 6, the connector 4 and the discharged battery 14. If there is sufficient current, the sensor 6 includes a switch 9 at the input 13. The included switch 9 partially shunts one arm of the divider 7. In this case, the voltage at the output 12 of the divider 7 corresponding to the voltage on the discharged battery 14, below a predetermined threshold Uad. and the threshold element 11 provides to the control input 10 of the switch 8 a signal holding the switch 8 in the open state.

After as a result of charging the current source 1, the voltage on the battery 14 rises to a value of U ₁ (see figure 2), at which the voltage at the output 12 of the divider 7 with a partially shunted shoulder exceeds the value of U _ass , the threshold element 11 is the output signal turns on the switch 8, acting on it at the input 10. The current of the source 1 is switched to the circuit of the switched switch 8, and the circuit with the diode 5 and the current sensor 6 is de-energized.

In the absence of current, the sensor 6 turns off the switch 9 at the control input 13, removing partial shunting of the arm of the divider 7 and, thereby, additionally increasing the voltage at the output 12 of the divider 7. The battery 14 is discharged through a divider 7 connected in parallel to the connector 4. The discharge of the battery 14 continues to as long as the voltage on it does not drop to a voltage of U ₂ , at which the voltage at the output 12 of the divider 7 with the unshunted arm does not fall below the value of U _ass . In this case, the threshold element 11 switches back and returns the switch 8 to the open state, in which the charging current of the source 1 again flows through the diode 4 and the sensor 6, charging the battery 14.

The repetitive charge-discharge process of the battery 14 can be stopped by fixing the closed state of the switch 8, for example, by reducing the value of U _ass to zero after a specified time.

The battery charge is accelerated due to its asymmetric recharging after pre-charging with a constant current [7].

Information sources

1. pat. RU 951554 U1 IPC H02J 7/00, 1982

2. pat. RU 17242 U1 IPC H02J 7/00, 2001

3. pat. RU 2091953 U1 IPC H02J 7/02, 1997

4. pat. RU 2284077, IPC H02J 7/02, 2006

5. pat. RU 2293402, IPC H02J 7/00, 2007

6. pat. RU 75796 U1 IPC H02J 7/00, 2008

7. Chemical sources of current: Reference. Ed. N.V. Korovina and A.M. Skundina. - M.: Publishing House MPEI, 2003, p. 362.

Claims (1)

A device for multi-post charging of batteries containing a current source to which charging posts are connected in series, each of which is equipped with a bypass contactor, a battery connector configured to mechanically open the bypass contactor, a diode and a current sensor connected in series with the battery connector, a voltage resistor divider, connected in parallel to the battery connector, the first switch bypass bypass, and the second switch ohm, partially shunting the arm of the resistor divider, while the control input of the first switch through a threshold element is connected to the output of the resistor voltage divider, and the control input of the second switch is connected to the output of the current sensor.