KR100242780B1 - Digital timing relay - Google Patents

Abstract

The present invention relates to a digital timing relay in which the internal configuration of the timing relay is digitized to eliminate the control error and the operation variation error.

The present invention provides a digital timing relay including a relay which is operated by receiving an AC commercial voltage to control a driving state of a target device, the digital timing relay comprising: a relay driver for controlling a magnetization state of the relay; A power converter converting the AC commercial voltage into a driving voltage and supplying the component voltage to each component; An oscillator for generating an oscillation clock of a predetermined frequency; A time setting unit composed of at least one dip switch operable by a user and outputting a setting time set by the user as binarized setting time information; And counting by dividing the oscillation clock of the oscillation unit, analyzing the setting time through the setting time information output from the time setting unit, comparing the analyzed setting time with the counting time, and counting time and the setting time. If this is the same, the digital timing relay includes a processor for controlling the magnetization of the relay by outputting a relay driving signal to the relay driver.

Therefore, by digitizing the time setting method using the dip switch, there is an advantage in that an error in the setting time can be suppressed, thereby ensuring a stable driving state of the digital timing relay.

Description

Digital timing relay

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a digital timing relay, and more particularly, to a digital timing relay in which the internal configuration of the timing relay is digitized to eliminate control and operating error.

The present invention also relates to a digital timing relay in which a power conversion circuit for converting a commercial voltage from a domestic commercial voltage into a driving voltage of a timing relay is improved.

In addition, the present invention enables to set the relay on time (Relay On Time) and the relay off time (Relay Off Time) at the same time by using one timing relay, so that it is possible to continuously repeat the driving state of the timing relay A digital timing relay.

The present invention also relates to a digital timing relay equipped with a display unit for displaying a counting state so that the setting state and the operation state can be visually checked.

In general, a timing relay is a device for controlling a driving state of a target device through time control, and is widely known as a core component of an industrial automation system for realizing automation of manufacturing and production processes. The conventional timing relay divides and counts a clock oscillated by a crystal oscillator in units of time (seconds, minutes and hours), and supplies a relay operating current at a corresponding time set by a user to magnetize the relay so that the driving power supplies the corresponding device. It is designed to be supplied or shut off. Conventional timing relays include a regulator capable of varying the resistance value of the variable resistor or the capacitance of the capacitor, and the main method is mainly an analog method in which the switching time of the relay can be arbitrarily set by operating the regulator. .

However, according to the conventional analog timing relay as described above, the following problems occur.

(1) As the user adopts the analog method of manipulating the controller to adjust the set time, the time cannot be set accurately because the manipulator operates according to the artificial judgment of the operator.

(2) The control error of the target equipment occurs due to the error of the setting time, and therefore, the exact control operation cannot be realized.

(3) Since the conventional analog timing relay can control only one of the on and off states of the contact according to the magnetization state of the relay, at least two timing relays are provided to simultaneously control the on and off states of the relay. shall. Therefore, the economic burden is increased and the installation environment is restricted.

(4) In the conventional analog timing relay, since there is no function of displaying the set time and counted time, the operator could not confirm the set time and counting time.

(5) In converting the domestic commercial power supply (110V to 220V) into the driving power supply (for example, '5V') of the relay and the internal component, a bulky power converter such as a transformer is required, so that the timing relay can be miniaturized. There was a problem of difficulty.

Accordingly, an object of the present invention is to solve the above-described problems, and a first object of the present invention is to provide a digital timing relay in which a time setting method is digitized, thereby suppressing an error in setting time.

In addition, a second object of the present invention is to provide a digital timing relay capable of precise control of a target device by suppressing occurrence of an error in a set time.

In addition, a third object of the present invention is to provide a digital timing relay capable of automation, economical, and is not limited by the installation environment by enabling to simultaneously set the on time and the off time of the relay.

In addition, a fourth object of the present invention is to provide a digital timing relay that enables the operator to easily check the set time and counting time.

Further, a fifth object of the present invention is to provide a digital timing relay capable of realizing miniaturization of a timing relay by employing a simple power conversion circuit composed of a resistor and a capacitor.

1 is a perspective view of a digital timing relay according to the present invention;

2 is an internal circuit diagram of a digital timing relay according to the present invention;

3 is a view illustrating data setting format of a time setting unit shown in FIG. 2;

4 is a waveform diagram according to an off time and an on time of a relay set by the twin timer setting unit illustrated in FIG. 2.

<Description of the symbols used in the main parts of the drawing>

1: digital timing relay 2: display window

3, 3a: Dip switch 4: Terminal

5: relay 6: relay drive unit

7: power converter 8: oscillator

9: time setting section 10: display section

11: processor 12: counting unit setting unit

13: twin timer setting section 14: forced reset section

15: Photo Coupler 16: Crystal Oscillator

17, 17a: 7-segment display element RELAY ON: relay drive signal

C1, C2: capacitors R1, R2, R3: resistors

Vcc: drive voltage BD: bridge diode

ZD1, ZD2: Zener Diode SW1, SW2, SW3: Switching Element

RESET: Reset terminal Q1: PNP type transistor

A feature of the present invention for achieving the above object is a digital timing relay including a relay which is operated by applying an AC commercial voltage to control a driving state of a target device: a relay for controlling the magnetization state of the relay A drive unit; A power converter converting the AC commercial voltage into a driving voltage and supplying the component voltage to each component; An oscillator for generating an oscillation clock of a predetermined frequency; A time setting unit composed of at least one dip switch operable by a user and outputting a setting time set by the user as binarized setting time information; And counting by dividing the oscillation clock of the oscillation unit, analyzing the setting time through the setting time information output from the time setting unit, comparing the analyzed setting time with the counting time, and counting time and the setting time. If the same, the digital timing relay including a processor for controlling the magnetization of the relay by outputting a relay drive signal to the relay driver.

In the above aspect of the present invention, the power converter includes a capacitor and a resistor connected in series with the AC commercial voltage to drop the AC commercial voltage; A bridge diode for full-wave rectifying the AC voltage dropped by the capacitor and the resistor; A zener diode for maintaining the voltage level rectified by the bridge diode at a driving voltage level; And a smoothing capacitor that smoothes the driving voltage waveform maintained at the predetermined level by the zener diode.

In addition, a zener diode which stabilizes the driving voltage to a predetermined level and consumes the driving voltage itself when the driving voltage falls below a switching point; A PNP transistor which is shared between the base terminal and the emitter terminal so that the driving voltage converted by the power converter is simultaneously applied, and the collector terminal is connected to the processor; And a forced reset part including at least one current sensing resistor for classifying the driving voltage supplied to the base terminal of the PNP type transistor so that the PNP type transistor is activated when the driving voltage is supplied.

The forced reset unit may further include a switching device connected to the processor and the ground terminal, respectively, so that the user can artificially manipulate the forced reset state from the outside.

The display apparatus may further include a display unit configured to receive the setting time information set by the time setting unit and the counting time information counted by the processor from the processor.

Further, it is preferable that the display portion is a 7-segment display element; In this case, the processor may be configured to simultaneously input / output the setting time information from the time setting unit and the setting and counting time information displayed on the display unit through a common input / output terminal.

The apparatus may further include a counting unit setting unit configured to switch a switching unit to selectively supply a driving voltage and a ground potential to the processor so as to change the time unit counted according to the connection state of the switching element; In this case, when the switching device is connected to supply the ground potential to the processor, the processor counts a counting time by any one time unit of one second, one minute, or one hour, and supplies a driving voltage to the processor. If the switching device is connected, it is preferable that the counting time is set to count by any one time unit of 0.1 second, 0.1 minute or 0.1 hour.

The apparatus may further include a twin timer setting unit configured of a switching device configured to switch a driving voltage or a ground potential to be selectively supplied to the processor to set the off time and the on time of the relay, respectively; In this case, the processor is set to set only the on time of the relay when the switching device is connected to supply the ground potential to the processor, and the switching device is connected to supply the driving voltage to the processor. In this case, it is preferable to set the off time and the on time of the relay, respectively.

Hereinafter, a preferred embodiment of a digital timing relay according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view of a digital timing relay according to the present invention.

As shown in FIG. 1, a display window 2 is formed on the front of the digital timing relay 1 so that the user can check the setting time and the counting time. In addition, a pair of dip switches 3 and 3a are mounted at a point adjacent to the display window 2 so that an arbitrary number is set within a range from 0 to 9 as the user operates the dip switches 3 and 3a. It was.

In addition, a plurality of terminals 4 are arranged on the back of the digital timing relay 1 so that the user can connect the A contact or the B contact or the like of the load or the relay to the terminal 4.

2 shows an internal circuit diagram of the digital timing relay 1 according to the present invention.

The internal circuit of the digital timing relay 1 shown in FIG. 2 is, in general, a relay driver 6 for controlling the magnetization state of the relay 5 and a power converter for converting an AC commercial voltage into a drive voltage Vcc. (7), an oscillation unit 8 for generating an oscillation clock of a predetermined frequency, a time setting unit 9 for setting a time to be controlled by a user using the dip switches 3 and 3a, and the display window (2) using the display unit 10 for displaying the counting time and the set time, the processor 11 for controlling each of the components, and the unit of counting time 1 second unit (1 minute or Counting unit setting unit 12 for selecting whether to set in units of 1 hour) or in units of 0.1 seconds (may be set in units of 0.1 minutes or 0.1 hours depending on the product concerned), and digital timing relay (1). ) Is set to operate as an On Timer. A twin timer setting unit 13 for selecting whether to set or to operate as a twin timer, and forcibly reset the processor 11 when the relay 5 is magnetized after the set time has elapsed. It is divided into the forced reset part 14.

In more detail, the relay driver 6 is operated by a relay drive signal RELAY ON applied from the processor 11 to supply the AC 5V (110V or 220V) to the relay 5. It is comprised by the photo coupler 15.

In addition, the power converter 7 includes a capacitor C1 and a resistor R1 connected in series to reduce the AC commercial voltage to a driving voltage Vcc (for example, '5V'), and the capacitor C1 and the capacitor C1. A bridge diode BD for full-wave rectifying the drive voltage Vcc of the alternating current voltage dropped by the resistor R1, a zener diode ZD1 for maintaining the drive voltage level, and a smoothing capacitor C2. The power converter 7 preferably connects a capacitor discharge resistor in parallel with the capacitor C1.

The oscillator 8 is constituted by a crystal oscillator 16 that generates an oscillation clock having a predetermined frequency.

On the other hand, the display unit 10 is composed of a pair of 7-segment display elements 17 and 17a, and has a structure in which each segment is connected to an input / output terminal of the processor 11.

The time setting section 9 is composed of a pair of dip switches 3 and 3a capable of setting 4-bit binary data, and each terminal of the dip switches 3 and 3a is connected to the display section 10. The input / output terminal of (11) is connected in common and is configured to divide and set the setting time into a maximum of 16 sections by 4-bit binary data. However, since the time setting in a normal case exists in the range from 0 to 9, the pair of dip switches 3 and 3a allow the setting time to be set in the range from 0 to 99. In addition, when the digital timing relay 1 is selected to operate as a twin timer, the pair of dip switches 3 and 3a can set the off time and the on time, respectively. In such a case, the off time and on time can set each set time within the range of 0 to 9, respectively.

The counting unit setting unit 12 is composed of a switching element SW1 for switching the drive voltage Vcc supplied from the power converter 7 and the ground potential of the ground terminal to be selectively supplied to the processor 11. .

The twin timer setting unit 13 is constituted by a switching element SW2 for switching the driving voltage Vcc supplied from the power converter 7 and the ground potential of the ground terminal to be supplied to the processor 11. .

The forced reset unit 14 receives the driving voltage Vcc supplied from the power converter 7 at the same time as the base terminal and the emitter terminal, and the collector terminal is connected to the reset terminal RESET of the processor 11. A pair of current sensing resistors R2 and R3 for controlling the amount of current supplied to the PNP transistor Q1, the base terminal of the PNP transistor Q1, and the base terminal of the PNP transistor Q1. The Zener diode ZD2 controls the drive voltage Vcc level. In addition, the switching device SW3 is provided between the reset terminal RESET and the ground of the processor 11 so as to allow the user to artificially reset the digital timing relay 1 from the outside.

The processor 11 is driven by receiving the driving voltage Vcc converted by the power converter 7, detects the set time input from the time setting unit 9, and controls the driving of the display unit 10. At the same time, by determining the setting state of the counting unit setting unit 12, the oscillation clock generated by the oscillation unit 8 is divided to adjust the counting time, and the setting state of the twin timer setting unit 13 is determined to determine the digital timing relay. (1) to control the driving state, and reset in accordance with the reset signal from the forced reset unit 14 to repeat the counting operation, and outputs the relay drive signal (RELAY ON) to the photo coupler (6) in the relay drive unit (6) Turn on 15 to drive the relay 5 to perform various control operations.

The operation of the present invention having the configuration as described above is as follows.

When the AC commercial voltage is applied, the voltage is dropped to the driving voltage Vcc level by the capacitor C1 and the resistor R1 connected in series. That is, the power converter 7 uses the principle that the capacitor C1 acts as a load when the AC power is applied, and sets the capacitance of the capacitor C1 to an appropriate value so that the voltage C1 corresponds to the voltage level of the AC commercial voltage. Regardless, you can always get a constant voltage level. In addition, as the resistance value of the resistor R1 is set to an appropriate value, the voltage passing through the capacitor C1 drops to a predetermined level, and is then driven by the zener diode ZD1 for maintaining the driving voltage level. Final conversion to level. This is much more efficient in terms of size than in the general case of using a power conversion transformer, which makes it possible to realize the miniaturization of the digital timing relay 1.

The driving voltage Vcc dropped by the capacitor C1 and the resistor R1 is full-wave rectified by the bridge diode BD, and after the ripple component is removed by the zener diode ZD1, the smoothing capacitor C2 is applied to the smoothing capacitor C2. Is smoothed and converted into a DC voltage. At this time, the driving voltage (Vcc) level can be arbitrarily set according to the setting values of the capacitor (C1) and the resistor (R1), but usually 5V, 9V, 12V and the like are mainly used.

The driving voltage is supplied to the forced reset unit 14, and is classified into a current having a predetermined size by a pair of current sensing resistors R2 and R3. At this time, the resistance value of the pair of current sensing resistors R2 and R3 sets the value of the current sensing resistor R3 connected to the base terminal of the PNP transistor Q1 to a very large value, whereby the PNP transistor Q1 The micro terminal is supplied with a very small amount of microcurrent, thereby turning on the PNP transistor Q1. When the PNP transistor Q1 is turned on, the driving voltage Vcc is supplied to the reset terminal RESET of the processor 11 through the PNP transistor Q1, so that the processor 11 performs normal operation. .

On the other hand, after the user sets the switching element SW2 of the twin timer setting unit 13 to the on timer position (connected to supply the ground potential to the processor 11), the dip switch of the time setting unit 9 By operating (3, 3a) to set the set time, this set time data is input to the processor 11. The processor 11 stores the set time data input from the time setting unit 9 and outputs the binarization control data to the display unit 10 to display the set time for a predetermined time, and the oscillation unit is output from the oscillator 8. The clock is counted and the counted time information is output to the display unit 10 to control the counting time to be displayed. Here, the counting value set according to the operation amount of the dip switches 3 and 3a is as shown in FIG.

After that, when the counting time becomes the same as the set time, the processor 11 outputs the relay driving signal RELAY ON to the photo coupler 15, and the photo coupler 15 receives the relay driving signal RELAY ON. It is turned on to supply the driving voltage Vcc to the relay 5. Accordingly, the relay 5 is magnetized to connect a B contact (not shown) connected to the relay 5 to supply the drive voltage Vcc to the target device.

On the other hand, after the relay 5 is magnetized and the target device is started to operate, when the AC commercial voltage supplied to the digital timing relay 1 by the user's artificial operation or for other reasons is cut off, The component is switched to the driving stop state. At this time, the residual potential of about 0.2V is continuously supplied to the processor 11 by the capacitor C1, and the processor 11 is not completely switched to the reset state due to the residual potential. Therefore, a malfunction of the processor 11 occurs, which causes the driving state of the digital timing relay 1 to become unstable. In order to prevent this, a forced reset unit 14 is provided. In other words, the Zener diode ZD2 in the forced reset part 14 has a characteristic of self-consuming and absorbing the corresponding voltage when a voltage level below the switching point is supplied. Therefore, when the driving voltage Vcc is cut off, the minute residual potential is small. Is absorbed by the zener diode ZD2. Accordingly, the driving current is not supplied to the base terminal of the PNP transistor Q1, and the PNP transistor Q1 is turned off, and the ground potential is supplied to the reset terminal RESET of the processor 11. The processor 11 is switched to the reset state by the ground potential supplied to the reset terminal RESET to stop and initialize the counting operation and other various control operations. Then, when the AC commercial voltage is supplied again, the processor 11 starts a new counting operation and various control operations. Therefore, stable operation of the processor 11 can be guaranteed.

On the other hand, when the switching element SW1 in the counting unit setting unit 12 is connected to the ground, the processor 11 recognizes the counting time unit in units of 1 second (or minutes or hours), and the switching element SW1 Is connected to the driving voltage Vcc terminal, the processor 11 recognizes the counting time unit in 0.1 second (or minute or hour) units. Here, in the general case, the digital timing relay 1 is operated while the switching element SW1 is connected to the ground, and in a device requiring precise control, the switching element SW1 is connected to the driving voltage Vcc terminal. Compared to the case, it can be set to perform 1/10 times precision counting. In addition, the time unit counted according to the on-off state of the switching device SW1 may be arbitrarily set as the program of the processor 11 changes.

On the other hand, after setting the switching element SW2 of the twin timer setting unit 13 to the twin timer position (connected to supply the driving voltage Vcc to the processor 11), the dips of the time setting unit 9 By operating the positions 3 and 3a to set the off time and the on time (see Fig. 4) of the relay 5, the off time and the on time of the relay 5 are input to the processor 11. The processor 11 stores the set time data input from the time setting unit 9 into off time and on time, and outputs binarization control data to the display unit 10 to store the off time and on time, respectively. It displays for a predetermined time, counts the oscillation clock output from the oscillator 8, and outputs the counted time information to the display unit 10 to control the counting time is displayed.

Thereafter, when the counting time becomes the same as the on time, the processor 11 outputs the relay driving signal RELAY ON to the photo coupler 15, and the photo coupler 15 receives the relay driving signal RELAY ON. It is turned on to supply the AC commercial voltage to the relay 5. Accordingly, the relay 5 is magnetized to connect a B contact (not shown) connected to the relay 5 to supply the AC compatible voltage to the target device.

On the other hand, the processor 11 starts a counting operation from the time when the relay 5 is magnetized, and when the counting time is equal to the off time, the processor 11 cuts off the relay driving signal RELAY ON supplied to the photo coupler 15, The coupler 15 is turned off as the relay driving signal RELAY ON is blocked. Accordingly, the AC commercial voltage supplied to the relay 5 is cut off so that the relay 5 is no longer magnetized, and the B contact of the relay 5 is opened so that the AC commercial voltage is no longer supplied to the target device. Therefore, when the digital timing relay 1 is operated as a twin timer, the magnetization state of the relay 5 is continuously repeated at a set off time and on time, so that the target device repeatedly performs the driving state and the stopping state. Done.

As a result, when the user sets the set time, the digital dip switches 3 and 3a can be used instead of the analog adjuster to eliminate the set time setting error so as to obtain a stable driving state of the digital timing relay. Can be.

Further, as the off time and the on time of the relay 5 are set by setting the twin timer, the magnetization state of the relay 5 is repeated at the set off time and on time, so that one digital timing relay 1 ) Can be used to control the start and stop of the target device at the same time.

As a result, according to the present invention as described above has the following advantages.

(1) By digitizing the time setting method using the dip switch, it is possible to suppress an error in the setting time, thereby ensuring a stable driving state of the digital timing relay.

(2) By mounting the 7-segment display unit at a predetermined position of the digital timing relay, the user can easily check the setting time and counting time.

(3) By adopting a simple power conversion circuit composed of a resistor and a capacitor, the digital timing relay can be miniaturized.

(4) By including a forced reset unit for resetting the counting operation of the processor after the relay is operated, it is possible to prevent the digital timing relay from malfunctioning, thereby ensuring a more accurate driving state.

(5) By further including a counting unit setting section composed of switching elements operable by the user, precise control of 0.1 second units or other arbitrarily set time units is possible.

(6) By further including a twin timer setting unit that can set the off time and on time of the relay at the same time, it becomes possible to implement an automation system that can automatically control the driving state of the target device, equipped with only one digital timing relay It is economical because it is possible to do so, it is not restricted by the installation environment.

Claims (11)

A digital timing relay comprising a relay operated under an AC commercial voltage to control a driving state of a target device: A relay driver for controlling the magnetization state of the relay; A power converter converting the AC commercial voltage into a driving voltage and supplying the component voltage to each component; An oscillator for generating an oscillation clock of a predetermined frequency; A time setting unit composed of at least one dip switch operable by a user and outputting a setting time set by the user as binarized setting time information; And The oscillation clock of the oscillation unit is divided and counted, the setting time is analyzed using the setting time information output from the time setting unit, the analyzed setting time is compared with the counting time, and the counting time and the setting time are And a processor configured to control the magnetization of the relay by outputting a relay driving signal to the relay driving unit if identical. The method according to claim 1, wherein the power converter, A capacitor and a resistor connected in series with the AC commercial voltage to drop the AC commercial voltage; A bridge diode for full-wave rectifying the AC voltage dropped by the capacitor and the resistor; A zener diode for maintaining the voltage level rectified by the bridge diode at a driving voltage level; And And a smoothing capacitor that smoothes the driving voltage waveform maintained at the predetermined level by the zener diode. The method according to claim 1, A zener diode which stabilizes the driving voltage to a predetermined level and consumes the driving voltage by itself when the driving voltage falls below a switching point; A PNP transistor which is shared between the base terminal and the emitter terminal so that the driving voltage converted by the power converter is simultaneously applied, and the collector terminal is connected to the processor; And And a forced reset unit comprising at least one current sensing resistor for classifying the driving voltage supplied to the base terminal of the PNP transistor so that the PNP transistor can be activated when the driving voltage is supplied. The method of claim 3, wherein the forced reset unit, And a switching element respectively connected to the processor and the ground terminal so that a user can artificially manipulate the forced reset state from the outside. The method according to claim 1, And a display unit for receiving the setting time information set by the time setting unit and the counting time information counted by the processor from the processor and displaying the setting time information. The method of claim 5, wherein the display unit, And a 7-segment display element. The method of claim 4, wherein the processor, And the input / output of the setting time information from the time setting unit and the setting and counting time information displayed on the display unit at the same time through a common input / output terminal. The method according to claim 1, And a counting unit setting unit configured to switch the supply of the driving voltage and the ground potential to the processor to change the time unit counted according to the connection state of the switching element. The method of claim 8, wherein the processor, When the switching device is connected to supply the ground potential to the processor, a counting time is counted by any one time unit of 1 second, 1 minute, or 1 hour, and the switching device is connected to supply a driving voltage to the processor. And counting time in one of 0.1 seconds, 0.1 minutes, or 0.1 hours, if any. The method according to claim 1, And a twin timer setting unit configured to switch to selectively supply a driving voltage or a ground potential to the processor to set the off time and the on time of the relay, respectively. The method of claim 10, wherein the processor, Set the ON time of the relay only when the switching device is connected to supply the ground potential to the processor, and set the off time of the relay when the switching device is connected to supply the driving voltage to the processor. Digital timing relay, characterized in that the set to set the on time and on.

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