DE29709951U1 - Portable voltage converter with built-in battery and connection sockets - Google Patents

Description

Description: An embodiment of the invention is shown in the drawing (sheet no. A). Where: A = the device,

B = the charging cable 12V, C = the charging cable 230V 50Hz, D = test connection cable. The device is switched on using switch 1 (S1 sheet no. A') in this state, LED 1 (X1 sheet no. A) lights up green and the socket (A1 sheet no. A) has voltage. After switch 1 is switched on, switch 2 (S2 sheet no. A) can be switched on in this state, LED (X2 sheet no. A) also lights up green and the test sockets L1/L2/L3 (PB sheet no. A) have voltage. If you only switch on switch 2, nothing happens, the device remains without voltage because switch 1 is the main on-off switch. If the device is charged using the charging cable 12V (B sheet no. A) nothing is displayed because the battery cannot be overcharged. When the device is charged with the 230 V 50 Hz charging cable (C sheet no. A), LED 3 (X3 sheet no. A) lights up green. If the fuse (F1 sheet no. A) trips (burns out) due to overload, LED 4 (X4 sheet no. A) flashes red. If the device is operated for too long without charging and the built-in battery becomes weaker, LED 5 (X5 sheet no. A) flashes red. The device does not switch off even if the battery voltage is too low and provides the output voltage until the battery is almost completely empty. (Intended for emergencies where light is needed until the very last moment). Functional description: When switch 1 (S1 sheet no. A and B) is switched on, the current flows from the battery via the fuse (F1 sheet no. A and B) via switch 1 to LED 1 (X1 sheet no. A and B)

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and to the battery control (BK sheet no. B) and the circuit board (P1 sheet no. B), where the direct current (12V -) is clocked to approx. 50 Hz via an electronic control (circuit) and brought to the transformer (T1 sheet no. B), this transforms the small voltage (approx. 9V) to the desired output voltage (approx. 240 V), the socket (A1 sheet no. A and B) has voltage. If you now switch on switch 2 (S2 sheet no. A and B), the current flows via switch 2 to LED 2 (X2 sheet no. A and B) and the test sockets L1/L2/L3 (PB sheet no. A and B) where voltage can now be taken.

When the fuse blows (F1 sheet no. A and B), the current flows through the parallel path (via the resistor to LED4), which flashes red. When charging the device with the 230V 50 Hz charging cable (C sheet no. A), the current flows from the mains to the transformer (T2 sheet no. B), where the voltage is transformed down (approx. 13 V) and flows to LED 3 (X3 sheet no. A and B) and the rectifier circuit (01 sheet no. B), where the alternating voltage is converted into direct current and smoothed with a capacitor and brought to the rechargeable battery, which is now charged. When the voltage of the rechargeable battery becomes too low (below 11V), the built-in battery control (BK sheet no. B) switches through and LED 5 (X5 sheet no. A and B) flashes red. If the device is charged via the 12V charging cable (B sheet no. A), the current flows via the charging cable to the rechargeable battery, which is then charged.

Technical data: Battery Sonnenschein dryfit battery 12V 6.5 Ah

Open circuit voltage socket 245 V Open circuit voltage sockets 245 V Voltage with resistive load 25W 218 V Frequency 50 Hz +/- 10 % Connected load max. 60 W resistive load Charging time via mains 230V 50 Hz approx. 20 h Efficiency: 70 - 80 % Charging time via 12V (vehicle) 1.5 to 2.5 h Operating time without charging at 25W resistive load 2 h

State of the art: Voltage transformers of conventional design do not have

has a built-in rechargeable battery and connection terminals, furthermore, there is no device with the features listed in claim 1 in the trade or electrical retail trade (e.g. Herman Albert Bumke, Königsstieg 81, 37081 Göttingen, electrical wholesaler ).

Problem:

The invention specified in claim 1 is based on the problem of creating a device that is portable and capable of supplying a sub-distribution with sufficient current (voltage) in order to check the electrical installation in the house (etc.) and at the same time a hand lamp can be connected to illuminate the workplace without the need for a mains connection.

Solution:

This problem is solved with the features listed in claim 1.

Achieved advantagesThe invention achieves that with

a portable, mains-independent device can supply a sub-distribution with enough current (voltage) in order to check the electrical installation (system) in a house, furthermore, a hand lamp (230 V) can be operated at the same time via the built-in socket in order to illuminate the workplace without the need for a mains connection.

Claims (2)

Protection claims: 1. Portable voltage converter with built-in Battery and connection sockets. characterized, - that the device has a socket on the front, - the device is equipped with an undervoltage control, - the device has two switches, - the device has a built-in battery, the device has a built-in charging transformer for 230V. - the device can also be charged via 12V, the device has connection sockets (test sockets), - the device has a fuse failure indicator, - the fuse and the charging device for 230V are on the back of the device. 2. Portable voltage converter according to the protection claim characterized in - the device has a charging cable for 12V, - the device has a charging cable for 230V 50Hz, - the device has a test connection cable, - the device is built into a plastic housing.