KR960011576B1 - Elevator stop floor display circuit - Google Patents

Abstract

a shifter register(1) storing the floor display data temporarily from a micro processor; inverters(I1-I8) inverting the output data of the shift register(1); a 2 input NAND gate part(2A-2H) receiving the output data(Q1-Q8) of the shift register(1) as one side input and receiving the output of the inverters as the other side input and inverting the inputs; kif relay parts(KRY1-KRY8) supplying the driving voltage to the segment terminals(A-G2) by the control of a reset signal(RE); and a constant voltage detecting relay(RY1) supplying the output voltage of a battery source power part(3) to the kif relay parts(KRY1-KRY8) when a constant voltage(P48V) is not inputted.

Description

Stop floor display circuit of elevator

1 is a stop-floor display circuit diagram of the elevator of the present invention.

2 is an electrostatic detection circuit diagram applied to the present invention.

3 is an electrostatic detection circuit diagram applied to the present invention.

* Explanation of symbols for main parts of the drawings

1: Microprocessor 2A-2H: 2 input NAND gate section

3: battery power unit I ₁ -I ₈ : inverter

KRY ₁ -KRY ₈ : Kiprilay

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a technology for displaying the current position of an elevator, and more particularly, to a stop floor display circuit of an elevator, which is capable of displaying a current position by driving an elevator floor indicator even when a power failure occurs using a kiprelay. will be.

In a typical elevator, once a power failure occurs and power is not supplied to the microprocessor, the current floor cannot be displayed, and the occupant may not be able to recognize the current floor. There was a problem that could not take a number of quick actions.

In order to solve the above problems, the present invention has been made so that the number of floors displayed before power failure can be continuously displayed by using a key relay, which will be described in detail with reference to the accompanying drawings.

1 is a stop floor display circuit diagram of an elevator of the present invention, and FIG. 2 is an electrostatic detection circuit diagram according to the present invention. As shown in FIG. 1, a shift register 1 for temporarily storing floor display data from a microprocessor and the shift The inverters I ₁ -I ₈ for inverting and outputting the output data of the register 1 and the output data Q ₁ -Q ₈ of the shift register 1 are the one-sided inputs, and the inverters I ₁ -I ₈ ) a two input NAND gate section 2A-2H for inverting and outputting the two inputs as the other input, and a set signal S and reset respectively outputted from the two input NAND gates 2A-2H. When the constant voltage P48V is not input by detecting the key relay KRY _{1 to} KRY ₈ , which supplies the driving voltage to the segment terminal AG ₂ under the control of the signal RE, and the input constant voltage P48V, supplying the output voltage of the power source (3) the key pressed to the relay ₍₁ KRY -KRY ₈₎ Be configured as a detection for the relay (RY _1), will be described in detail the operations and effects of the present invention configured in this way, see FIG. 3 as follows.

The current floor display data input through the data line of the microprocessor is stored in the shift register 1, and the output data Q ₁ -Q ₈ of the shift register 1 respectively represent the inverters I ₁ -I ₈ . Inverted through

The two input NAND gate units 2A-2H receive the outputs Q ₁ -Q ₈ of the shift register 1 as one input and the outputs of the inverters I ₁ -I ₈ as the other input. In response to the supply, the inverted output is driven, and the key relays KRY _{1 to} KRY ₈ are driven in accordance with the outputs of the two input NAND gate units 2A-2H, thereby driving the segment as shown in FIG.

For example, when the output Q ₁ of the shift register 1 is low, the row is directly supplied to the NAND gate ND ₁ and inverted to high through the inverter I ₁ . is supplied to ND _1), the NAND gate _{(ND 1), (ND 1} ') , respectively high, is low, the output Keefe relay (KRY ₁₎ a set signal (S), Li respectively supplied to a set signal (R) in Therefore, the key relay KRY ₁ is turned off, and thus power is not supplied to the segment terminal A. FIG.

On the other hand, when the output (Q1) of the shift register (1) is high, a high direct soon as supplied to the NAND gate (ND ₁₎ as well, is the reverse to the low through the inverters (I ₁₎ of NAND gate (ND ₁ ), (respectively a low, a high is output from the ND ₁₎ Keefe so respectively supplied to the relay (KRY ₁₎ the set terminal (S), a reset terminal (R) of the are that Keefe relay (KRY ₁₎ on, because of this Power is supplied to the segment terminal A. FIG.

According to the outputs Q ₂ -Q ₈ of the shift register 1, the remaining NAND gate portions 2B-2H and the kiprile KRY ₂ -KRY ₈ also have the NAND gate portion 2A and the kiprile KRY. ₁ ), and eventually, the segment shown in FIG. 3 can be driven by using the output value of the shift register 1.

Then, as shown in FIG. 2, when the power failure detection relay RY ₁ is turned on, that is, in a state not in the power failure, the power failure detection relay RY ₁ is opened to open the power failure detection relay RY ₁ . b, and the contact switch (RY _1), (RY ₁₎ is turned off blocking the battery power supply unit (3), whereas when a power failure occurs that the power failure detection relay (RY ₁₎ is turned off the power failure detection relay (RY ₁₎ of the b-contact switch _{(RY 1), (RY 1} ) is short-circuited, the output voltage of the battery power supply 3, the b-contact switch _{(RY 1), (RY 1} ) and the relay Keefe (KRY ₁ -KRY ₈₎ It can be supplied to the common line of the segment to continue to drive the segment as shown in FIG.

As described in detail above, the present invention enables the occupant to recognize the current floor by continuously displaying the total number displayed before the blackout, even when the blackout is used, and the elevator monitor can stop the current elevator. It is effective to know the floor accurately and take action quickly.

Claims (2)

A shift register 1 for temporarily storing the layer display data from the microprocessor, an inverter I ₁ -I ₈ for inverting and outputting the output data of the shift register 1, and output data of the shift register 1 the Q ₁ -Q ₈₎ to one side input, and wherein the inverter (I ₁ -I | and ₈₎ output by the other input to the second input the inverted output two-input NAND gate portions (2A-2H) for the said 2 Key preliminaries KRY _{1 to} KRY ₈ for supplying a driving voltage to the segment terminal AG ₂ under the control of the set signal S and the reset signal RE respectively output from the input NAND gates 2A-2H. When the constant voltage P48V is not detected and the constant voltage P48V is not input, the output voltage of the battery power supply unit 3 is supplied to the power failure detection relay RY ₁ that supplies the key relay KRY _{1 to} KRY ₈ . A stop floor display circuit for an elevator, which is configured. Claim 1 wherein in Keefe relay (KRY ₁₎ is a diode (D _1, D ₁ 'between the connection to the power supply terminal (P5V) to the set terminal and the power supply terminal wherein the second input of NAND gate portion (2A) of (P5V) in ) Is a stop floor display circuit of an elevator characterized in that the configuration is connected in parallel.