JPH0441362B2 - - Google Patents

Description

[Detailed description of the invention] [Technical field] This invention is installed in a building as a control panel,
This relates to a control device that operates an air conditioner, a water pump, etc.

[Background technology]

The control device that forms the basis of this invention is a main body block as shown in FIG. 1A, which is mounted on a single printed wiring board and attached to the main body of a control panel case.
The main block _BK is mounted on one printed wiring board and attached to the lid of the control panel case, with two power lines (r line, s line: AC24V) and one dedicated line _L1 . ₁ and a lid block BK ₂₁ as shown in FIG.

This will be explained in more detail below. First, press the local selection button to turn on local selection switch SW ₁ , turn off selection switch SW ₂ , and turn off remote selection switch SW _3.
This section explains what happens when you turn OFF. In this state, when switch PB _ON1 is turned on, r line → switch PB _OFF → diode D ₁ → switch
PB _ON1 → Hand selection switch SW ₁ → Dedicated line L ₁ → Diode D ₃ → Resistor R ₂ → Relay X ₁ → Transistor Q ₂
→ Diode D ₄ → Half-wave current is applied on one side through the s line path, relay X ₁ is energized, and the contact of relay X ₁
x ₁ turns on. As a result, the R line - current transformer
CT - contact x ₁ of relay X ₁ - electromagnetic contactor MC - contact tm of thermal relay - energized through the S line path, and electromagnetic contactor MC is excited and becomes operational. Also, when an excitation current flows through the magnetic contactor MC, the current detection circuit DT transfers this excitation current to the current transformer.
Detect through CT and turn on transistor _Q4 . As a result, transistor _Q5 has a diode
Base current flows through D ₁₃ , resistor R ₁₀ , and transistor Q ₄ , turning on transistor Q ₅ . When this transistor _Q5 turns on, the s line →
Transistor Q ₅ → Diode D ₉ → Issuing diode LED ₁ → Dedicated line L ₁ → Diode D ₈ → Resistor R ₈ , R ₉
→The light emitting part of photocouplers PC ₁ and PC ₂ → The other side is half-wave energized through the r line path, and the r line → switch
PB _OFF → Between emitter and base of transistor Q ₁ →
Resistor R ₁ → Light receiving part of photocoupler PC ₁ → Diode
One side is energized half-wave in the D ₇ → s line path, transistor Q ₁ is turned on, and the r line → switch is turned on.
PB _OFF → Transistor Q ₁ → Diode D ₂ → Hand selection switch SW ₁ → Dedicated line L ₁ → Diode D ₃ → Resistor R ₂ → Relay X ₁ → Transistor Q ₂ → Diode
Half-wave current is applied to one side through the D ₄ →s line path, relay X ₁ becomes self-holding state, and magnetic contactor MC maintains the excited state. Further, the light receiving section of the photocoupler PC ₂ is turned on, the indicator light circuit DP lights up the operation indicator lamp RL, and the light emitting diode LED ₁ is also turned on. Note that the diode bridge DB ₂ and capacitor C ₃ are for the power supply of the current detection circuit DT. Furthermore, the light emitting diode LED ₂ is also turned on by supplying base current to the transistor Q ₂ through the resistor R ₃ .

As mentioned above, the auxiliary contact of the magnetic contactor MC is eliminated and the exciting current is detected by the current detection circuit DT.
When transistors Q ₄ and Q ₅ are turned on and off to take out the auxiliary contact output, the main block BK ₁
When mounted on a printed wiring board, the number of connecting wires between the printed wiring board and the electromagnetic contactor MC can be reduced to two, and wiring can be simplified.

Next, when the switch PB _OFF is turned off, the energization to the winding of the relay X ₁ is stopped, the self-holding of the relay X ₁ is released, the magnetic contactor MC becomes a de-energized state, and the operation is stopped. Further, the light receiving section of the photocoupler PC ₃ is turned off, and the indicator lamp circuit DP turns off the operation indicator lamp RL and turns on the stop indicator lamp GL.

Next, in an operating state where the self-holding state _of relay The current supply stops and operation is stopped, the output of the current detection circuit DT disappears, transistors Q ₄ and Q ₅ turn off, and the self-holding of relay X ₁ is released.
Operation indicator lamp RL goes out. Also, by switching contact tm to the normally open side, R line - resistance R ₁₁
- Diode bridge DB ₃ - Resistor R ₁₅ - Light emitting part of photocouplers PC _4A and PC _4B - Diode bridge
DB ₃ - Resistor R ₁₂ - Contact tm - The light receiving part of photocoupler PC _4A is turned on by energizing through the S line path.
Resistor R ₁₇ , photocoupler PC _4A photodetector, diode
Base current flows through _D14 to transistor _Q6 . As a result, s line → flicker circuit FC → transistor Q ₆ → diode D ₁₀ → light emitting diode
LED ₁ → Dedicated line L ₁ → Diode D ₈ → Resistor R ₈ , R ₉ →
The light emitting part of the photocouplers PC ₁ and PC ₂ is intermittently energized in half-wave on the other side through the path of the r line, and the transistor Q _1
is intermittently _turned on and _{tries to energize} relay This allows the light emitting diode LED ₂ to bypass the base current flowing into the transistor Q ₂ through the resistor R ₃ and
Q ₂ is turned off and relay X ₁ is prohibited from being energized.
In addition, the light receiving part of photocoupler PC ₂ turns on intermittently, causing the indicator light circuit DP to turn on the error indicator lamp.
OL lights up and light emitting diode LED ₁ also flashes.

Next, in an abnormal state, when the contact tm of the thermal relay is reset (returned to the normally closed side), the power to the photocouplers PC _4A and PC _4B is stopped, the light receiving part of the photocoupler PC _4A is turned off, and the photocoupler
The intermittent half-wave energization to the light emitting parts of PC ₁ and PC ₂ on the other side stops, the light receiving part of photocoupler PC ₁ is turned off, transistor Q ₁ is completely turned off, and the light receiving part of photocoupler PC ₂ is also turned off. Indicator light circuit
DP turns off the abnormality indicator lamp OL, turns on the stop indicator lamp GL, and also turns off the light emitting diode LED ₁ . Furthermore, by turning off the light receiving section of the photocoupler PC _4B , the transistor Q ₃ is turned off, the prohibition of turning on the transistor Q ₂ is lifted, and the prohibition of excitation of the relay X ₁ is canceled. In this way, when the thermal relay trips, the transistor
As a result of turning off Q ₂ and prohibiting the excitation of relay X ₁ , the photocoupler is removed from the flicker circuit FC.
Even if the light emitting part of PC ₁ is intermittently energized, its light receiving part is intermittently turned on, and transistor Q ₁ is intermittently turned on, relay X ₁ is not energized at all and current flows from the flicker circuit FC. Photocoupler PC ₁
Even if you reset the thermal relay while the light emitting part is on (there is a slight delay in turning off the light due to capacitor _C2 ), it will not go into operation and it is safe.

Next, in the stopped state, when external contact Z is turned on, R line - external contact Z - resistor R ₁₃ - diode bridge DB ₄ - resistor R ₁₆ - photocoupler
Light emitting part of PC ₅ - Diode bridge DB ₄ - Resistor
R ₁₄ - Photocoupler is energized through the S line path.
The light receiving section of PC ₅ turns on. As a result, the resistance R ₁₈ ,
The base current flows into the transistor Q ₇ through the light receiving part of the photocoupler PC ₅ and the diode D ₁₅ , turning on the transistor Q ₇ , and then through the resistor R ₁₉ , the transistor Q ₇ , and the diode D ₁₅ .
Base current flows through _Q8 , turning on transistor _Q8 . Therefore, r line → transistor
Q ₈ → Diode D ₅ → _Resistor R ₂ → Relay X ₁ → Transistor Q ₂ → Diode D ₄ → _The s line is about to be energized. Light emitting part → Light emitting diode LED ₁ → Dedicated line L ₁ → Hand selection switch
SW ₁ → Switch PB _ON2 → Resistor R ₆ → Diode D ₁₂
→ Half-wave current is applied to one side through the s line path, and the light receiving part of photocoupler PC ₃ turns on, turning on transistor Q ₃ , turning off transistor Q ₂ , and turning on the relay.
Prohibit excitation of X ₁ . In this way, external contact Z
When _switch SW ₁ is turned on, transistor Q ₂ is turned off and excitation of relay be able to. Moreover, the main body block BK ₁ and the lid block
Only one dedicated line _L1 is required to connect BK ₂₁ .

Next, press the remote selection button and switch to the local selection switch.
A case will be explained in which SW ₁ is turned OFF, off selection switch SW ₂ is turned OFF, and remote selection switch SW ₃ is turned ON. In this state, when external contact Z is turned on, R line - external contact Z - resistor R ₁₃ - diode bridge DB ₄ - resistor R ₁₆ - photocoupler PC ₅
Light emitting part − Diode bridge DB ₄ − Resistor R ₁₄ −
Power is applied through the S line path, the light receiving part of the photocoupler PC ₅ is turned on, transistors Q ₇ and Q ₈ are turned on, and the r line → transistor Q ₈ → diode D ₅ → resistor R ₂ → relay X ₁ → transistor Q ₂ →
Diode D ₄ → Half-wave current is applied through the s line path,
Relay X ₁ is energized and contact x ₁ is turned on, energizing the electromagnetic contactor MC and putting it into operation. Further, the current detection circuit DT detects the excitation current and turns on the transistors Q ₄ and Q ₅ . As a result,
s line → diode D ₉ → light emitting diode LED ₁
→ Dedicated line L ₁ → Diode D ₈ → Resistors R ₈ , R ₉ → Light emitting parts of photocouplers PC ₁ , PC ₂ → Half-wave current is applied to the other side through the r line path, and the light receiving part of photo coupler PC ₂ is turned on. The indicator light circuit DP lights up the operation indicator lamp RL, and the light emitting diode LED ₁ also lights up.

Next, when external contact Z is turned off, power to the light emitting part of photocoupler PC ₅ is stopped, and the photocoupler
When the light receiving part of PC ₅ is turned off, the transistor Q ₇ ,
Q ₈ is turned off, relay X ₁ is no longer energized, and
Contact _x1 is turned off, and the magnetic contactor MC becomes de-energized, and the operation is stopped. Furthermore, by eliminating the excitation current, transistors Q ₄ and Q ₅
is turned off, power to the light emitting part of photocoupler PC ₂ is stopped, the light receiving part of photocoupler PC ₂ is turned off, and the indicator light circuit DP turns off the operation indicator lamp RL, turns on the stop indicator lamp GL, and starts emitting light. Diode LED ₁ also turns off.

During operation with the external contact Z turned on, when the thermal relay trips and the contact tm switches to the normally open side, the excitation of the electromagnetic contactor MC is stopped and the operation is stopped. In addition, as the excitation current disappears, transistors Q ₄ and Q ₅ are turned off, power to the light emitting part of the photocoupler PC ₂ is stopped, the light receiving part is turned off, and the indicator lamp circuit DP turns off the operation indicator lamp RL. Turn off the light. Furthermore, the photocoupler
Turn on power to PC _4A and PC _4B to turn on their light receiving sections. As a result, s line → Fritzker circuit FC →
Transistor Q ₆ → Diode D ₁₀ → Light emitting diode LED ₁ → Dedicated line L ₁ → Diode D ₈ → Resistor R ₈ , R ₉
→ Light emitting parts of photocouplers PC ₁ and PC ₂ → The r line is intermittently energized, and the indicator light circuit DP lights up the error indicator lamp OL. Also, by turning on the light receiving part of photocoupler PC _4B , the transistor
Turn off Q ₂ and inhibit energization of relay X ₁ .

After that, when the thermal relay is reset, the power to the light emitting parts of photocouplers PC _4A and PC _4B is stopped.
Those light receiving sections are turned off. As a result, the indicator light circuit DP turns off the abnormality indicator lamp OL and turns on the stop indicator lamp GL, and also turns off the transistor _Q2.
Turn on to release the prohibition of excitation of relay _X1 .

Next, press the OFF selection button and turn on the hand selection switch.
The case where SW ₁ is OFF, off selection switch SW ₂ is ON, and remote selection switch SW ₃ is OFF will be explained. In this state, relay _X1 is not energized at all even if switch PB _ON1 is turned on. Also, when external contact Z is turned on, transistor Q ₈
turns on, R line → Transistor Q ₈ → Diode D ₅ → Resistor R ₂ → Relay X ₁ → Transistor
Q ₂ → diode D ₄ → s line path is trying to energize, but r line → transistor Q ₈ → diode D ₅ → light emitting part of photocoupler PC ₃ → light emitting diode LED ₁ → exclusive line L ₁ → off selection switch SW ₂ →
Resistor R ₇ → diode D ₆ → s line is energized for half a wave on one side, and the light receiving part of photocoupler PC ₃ is turned on, transistor Q ₃ is turned on, and transistor Q ₂ is turned on.
is turned off, prohibiting the excitation of relay _X1 , and the stop indicator lamp GL lights up.

_C1 is a capacitor that delays the excitation stop of relay _X1 for a certain period of time. _C11 is a diode, _DB1 is a diode bridge, and _C4 and _C5 are capacitors.

Switch PB _ON2 cuts off the current flowing to resistor _R6 the moment switch PB _ON1 is pressed, and r-
This is to prevent voltage drop on the s line and to make it easier for relay _X1 to be energized even if the power supply voltage drops.
You don't have to. Once relay _X1 is turned on, it will not open even if the voltage drops slightly, so there is no problem even if switch BP _ON2 is turned on afterwards.

However, in such a configuration, priority is given to the "distant" state, and when a failure occurs in the off selection switch SW ₂ , the off selection switch SW ₂ is turned on even though the operator operates the off selection button. Otherwise, the device will be in a "distant" state, and the external contact Z will open and close in response, causing it to operate unexpectedly when the operator is performing an inspection by turning it off, which is extremely dangerous. Ta. Also, if the push button is not pressed completely (half-pressed, etc.), the off selection switch SW ₂ will turn ON.
However, in this case as well, "distant"
The situation was extremely dangerous.

[Purpose of the invention]

An object of the present invention is to provide a control device that can prioritize the "off" state and improve safety.

[Disclosure of the invention]

The control device of the present invention includes a one-way energizing type hand switch D _{1 whose} one end is connected to one power line r,
PB _ON1 , two-way conduction type indicators PC ₂ and DP each having one end connected to the one power supply line r, and first and second one-way conduction type directional devices each having one end connected to the other power supply line s. One end of the elements D ₁₂ and D ₆ is connected to the other end of the one-way energizing type hand switch D ₁ , PB _ON1 and the other end of the first unidirectional energizing type directional element D ₁₂ , and the other end is connected to the other end of the one-way energizing type hand switch D 1 , PB ON1. The other end is connected to the other end of the type display device PC ₂ , DP and the other end of the second one-way energizing type directional element D ₆ , which turns on in response to a local selection operation, and also turns off in response to an off-selection operation and a remote selection operation. a hand selection switch SW ₁ that is turned off in response to each selection operation; and a second unidirectional current-carrying type directional element connected to the other power supply line s.
A switch is inserted into the path leading to the other end of the local selection switch SW ₁ via _D6 , and is turned on in response to an off selection operation and turned off in response to both a local selection operation and a remote selection operation. selection switch
SW ₂ and a switch Q ₁₁ , which is provided in parallel with the off selection switch SW ₂ and opens in response to a local selection operation and a remote selection operation, respectively.
A series circuit of main relay X ₁ and normally closed contact Q ₂ that constitutes BK ₂₂ and has one end connected to the other power supply line s, and the other end of the series circuit of main relay X ₁ and normally closed contact Q ₂ . Third unidirectional current-carrying type directional element with one end connected
An auxiliary relay PC ₃ is connected in parallel to the one-way conduction type directional element D _{3 and} drives the normally closed contact Q ₂ to open.
and the one power line r and the main relay X ₁
and unidirectional current-carrying type external contacts D ₅ , Q ₈ :Z connected between the other end of the series circuit of normally closed contact Q ₂ , said other power supply line s and said third unidirectional current-carrying type directional A second block BK ₁ is constituted by normally open contacts Q ₅ and Q ₄ of the other direction connected to the other end of the element D ₃ and driven to close by _{the main relay X 1 .} The other end of the hand selection switch SW ₁ and the off selection switch SW ₂ and the other end of the third unidirectional energizing type directional element D ₃ are connected by a dedicated line L ₁ . be.

In this way, by providing a switch in parallel with the off selection switch that opens in response to both the local selection operation and the remote selection operation, the switch opens not only when the off selection operation is performed and the off selection switch is turned on. The "off" state can be set even when neither the local selection operation nor the remote selection operation is performed, and the "off" state can be given priority to improve safety.

Embodiment A first embodiment of the present invention will be described based on FIGS. 1A and 1B and FIG. 2. This control device has 1
The main body block BK 1 as shown in Fig. 1A is mounted on one printed wiring board and attached to the main body of the control panel case, and the main block BK ₁ is mounted on one printed wiring board and attached to the lid of the control panel case. The first line is connected to main block BK ₁ with two power lines (r line, s line: AC24V) and one dedicated line _L1 .
It consists of a lid block BK ₂₂ as shown in Figure B.

This will be explained in more detail below. First, press the local selection button, that is, in response to the local selection operation, turn on the local selection switches SW ₁ and SW ₄ , turn off the off selection switches SW ₂ and SW ₅ , and turn off the remote selection switch SW ₆ .
We will explain what happens when it is turned OFF. in this case,
By turning on the hand selection switch SW ₄ , the r line →
Diode D ₂₁ → Resistor R ₃₃ → Light emitting diode LED ₃
→ Hand selection switch SW ₄ → Half-wave energization is applied through the s line path, and light emitting diode LED ₃ lights up, indicating that it is in the "hand" state. Furthermore, by energizing this path, the voltage of the series circuit of resistors R ₃₁ and R ₃₂ drops to the forward voltage of the light emitting diode LED ₃ .
Therefore, the base-emitter voltage of transistor _Q11 becomes low, and transistor _Q11 is turned off.

In this state, when switch PB _ON1 is turned on, r line → switch PB _OFF → diode D ₁
→ Switch _ON1 → Local selection switch SW ₁ → Dedicated line
L _{1 → Diode} D ₃ → _Resistor R ₂ → _Relay
Contact x ₁ of X ₁ turns on. As a result, R line - current transformer CT - contact x _{1 of relay x 1 -} magnetic contactor
The MC-thermal relay contacts are energized through the tm-S line path, and the electromagnetic contactor MC is energized and becomes operational. Further, when an excitation current flows through the electromagnetic contactor MC, the current detection circuit DT detects this excitation current via the current transformer CT, and turns on the transistor _Q4 . As a result, transistor _Q5 has a diode
Base current flows through D ₁₃ , resistor R ₁₀ , and transistor Q ₄ , turning on transistor Q ₅ . When this transistor _Q5 turns on, the s line→
Transistor Q ₅ → Diode D ₉ → Light emitting diode LED ₁ → Dedicated line L ₁ → Diode D ₈ → Resistor R ₈ , R ₉
→The light emitting part of photocouplers PC ₁ and PC ₂ → The other side is half-wave energized through the r line path, and the r line → switch
PB _OFF → Between emitter and base of transistor Q ₁ →
Resistor R ₁ → Light receiving part of photocoupler PC ₁ → Diode
One side is energized half-wave in the D ₇ → s line path, transistor Q ₁ is turned on, and the r line → switch is turned on.
PB _OFF → Transistor Q ₁ → Diode D ₂ → Hand selection switch SW ₁ → Dedicated line L ₁ → Diode D ₃ → Resistor R ₂ → Relay X ₁ → Transistor Q ₂ → Diode
Half-wave current is applied to one side through the D ₄ →s line path, relay X ₁ becomes self-holding state, and magnetic contactor MC maintains the excited state. Further, the light receiving section of the photocoupler PC ₂ is turned on, the indicator light circuit DP lights up the operation indicator lamp RL, and the light emitting diode LED ₁ is also turned on. Note that the diode bridge DB ₂ and capacitor C ₃ are for the power supply of the current detection circuit DT. Furthermore, the light emitting diode LED ₂ is also turned on by supplying base current to the transistor Q ₂ through the resistor R ₃ . Furthermore, since the indicator light circuit DP is controlled by the photocoupler PC ₂ , in the claims, the indicator light circuit DP is controlled by the photocoupler PC ₂ and the indicator light circuit DP.
The combination of these is expressed as a energized in the other direction. Note that the indicator light circuit DP is connected to the power lines r and s via the diode bridge DB ₁ , but this is merely for supplying operating power, and the indication light circuit DP is connected to the power lines The expression "connected one end" refers to a photocoupler
This corresponds to the fact that the light emitting part of PC ₂ is connected to power line r.

As mentioned above, the auxiliary contact of the magnetic contactor MC is eliminated and the exciting current is detected by the current detection circuit DT.
When transistors Q ₄ and Q ₅ are turned on and off to take out the auxiliary contact output, the main block BK ₁
When mounted on a printed wiring board, the number of connecting wires between the printed wiring board and the electromagnetic contactor MC can be reduced to two, and wiring can be simplified.

Next, when the switch PB _OFF is turned off, the energization to the winding of the relay X ₁ is stopped, the self-holding of the relay X ₁ is released, the electromagnetic contactor MC becomes a de-energized state, and the operation is stopped. Further, the light receiving section of the photocoupler PC ₂ is turned off, and the indicator light circuit DP turns off the operation indicator lamp RL and turns on the stop indicator lamp GL.

Next, in an operating state where the self-holding state _of relay The current supply is stopped and the operation is stopped, the output of the current detection circuit DT disappears, transistors Q ₄ and Q ₅ are turned off, and the self-holding of relay X ₁ is released.
Operation indicator lamp RL goes out. Also, by switching contact tm to the normally open side, R line - resistance R ₁₁
- Diode bridge DB ₃ - Resistor R ₁₅ - Light emitting part of photocouplers PC _4A and PC _4B - Diode bridge
DB ₃ - Resistor R ₁₂ - Contact tm - The light receiving part of photocoupler PC _4A is turned on by energizing through the S line path.
Resistor R ₁₇ , photocoupler PC _4A photodetector, diode
Base current flows through _D14 to transistor _Q6 . As a result, s line → flicker circuit FC → transistor Q ₆ → diode D ₁₀ → light emitting diode
LED ₁ → Dedicated line L ₁ → Diode D ₈ → Resistor R ₈ , R ₉ →
The light emitting part of the photocouplers PC ₁ and PC ₂ is intermittently energized in half-wave on the other side through the path of the r line, and the transistor Q _1
is intermittently _turned on and _{tries to energize} relay This bypasses the light emitting diode LED ₂ and the base current flowing into the transistor Q ₂ through the resistor R ₃ and
Q ₂ is turned off and relay X ₁ is prohibited from being energized.
In addition, the light receiving part of photocoupler PC ₂ turns on intermittently, causing the indicator light circuit DP to turn on the error indicator lamp.
OL lights up and light emitting diode LED ₁ also flashes.

Next, in an abnormal state, when the contact tm of the thermal relay is reset (returned to the normally closed side), the power to the photocouplers PC _4A and PC _4B is stopped, the light receiving part of the photocoupler PC _4A is turned off, and the photocoupler
The intermittent half-wave energization to the light emitting parts of PC ₁ and PC ₂ on the other side stops, the light receiving part of photocoupler PC ₁ is turned off, transistor Q ₁ is completely turned off, and the light receiving part of photocoupler PC ₂ is also turned off. Indicator light circuit
DP turns off the abnormality indicator lamp OL, turns on the stop indicator lamp GL, and also turns off the light emitting diode LED ₁ . Furthermore, by turning off the light receiving section of the photocoupler PC _4B , the transistor Q ₃ is turned off, the prohibition of turning on the transistor Q ₂ is lifted, and the prohibition of excitation of the relay X ₁ is canceled. In this way, when the thermal relay trips, the transistor
As a result of turning off Q ₂ and prohibiting the excitation of relay X ₁ , the photocoupler is removed from the flicker circuit FC.
Even if the light emitting part of PC ₁ is intermittently energized, its light receiving part is intermittently turned on, and transistor Q ₁ is intermittently turned on, relay X ₁ is not energized at all and current flows from the flicker circuit FC. Photocoupler PC ₁
Even if you reset the thermal relay while the light emitting part is on (there is a slight delay in turning off the light due to capacitor _C2 ), it will not go into operation and it is safe.

Next, in the stopped state, when external contact Z is turned on, R line - external contact Z - resistor R ₁₃ - diode bridge DB ₄ - resistor R ₁₆ - photocoupler
Light emitting part of PC ₅ - Diode bridge DB ₄ - Resistor
R ₁₄ - Photocoupler is energized through the S line path.
The light receiving section of PC ₅ turns on. As a result, the resistance R ₁₈ ,
The base current flows into the transistor Q ₇ through the light receiving part of the photocoupler PC ₅ and the diode D ₁₅ , turning on the transistor Q ₇ , and then through the resistor R ₁₉ , the transistor Q ₇ , and the diode D ₁₅ .
Base current flows through _Q8 , turning on transistor _Q8 . Therefore, r line → transistor
Q ₈ → Diode D ₅ → _Resistor R ₂ → Relay X ₁ → Transistor Q ₂ → Diode D ₄ → _The s line is about to be energized. Light emitting part → Light emitting diode LED ₁ → Dedicated line L ₁ → Hand selection switch
SW ₁ → Resistor R ₆ → Diode D ₁₂ → One-side half-wave current is applied through the s line path, and the light receiving part of photocoupler PC ₃ turns on, turning on transistor Q ₃ , turning off transistor Q ₂ , and turning on relay X. Prohibits excitation of ₁ . In this way, when external _contact Z is turned on, transistor Q ₂ is turned off and excitation of relay X ₁ is prohibited. On/off can be completely disabled. Moreover, there is a dedicated line L ₁ connecting the main body block BK ₁ and the lid block BK ₂₂ .
You only need one.

Next, press the far selection button, that is, in response to the far selection operation, turn the local selection switches SW ₁ and SW ₄ .
OFF, the case where the off selection switches SW ₂ and SW ₅ are turned OFF and the remote selection switch SW ₆ is turned ON will be explained. In this case, by turning on the far selection switch SW ₆ , the r line → diode D ₂₁ → resistor R ₃₃ → light emitting diode LED ₅ → far selection switch SW ₆ → s
The light emitting diode is energized half-wave in the line path
LED ₅ lights up to indicate that the device is in the "far" state. Also, due to current flowing through this path, resistance
The voltage of the series circuit of R ₃₁ and R ₃₂ is the light emitting diode
The voltage drops to the forward voltage of LED ₅ , and therefore the base-emitter voltage of transistor Q ₁₁ becomes low.
Transistor _Q11 is turned off.

In this state, when external contact Z is turned on, R line - external contact Z - resistor R ₁₃ - diode bridge DB ₄ - resistor R ₁₆ - light emitting part of photocoupler PC ₅ - diode bridge DB ₄ - resistor R ₁₄ - Power is applied through the S line path, the light receiving part of photocoupler PC ₅ is turned on, transistors Q ₇ and Q ₈ are turned on, and the r line → transistor Q ₈ → diode
D ₅ → Resistor R ₂ → Relay X ₁ → Transistor Q ₂ → Diode D ₄ → Half-wave energization is applied through the s line path, relay X ₁ is energized, contact x ₁ is turned on, and electromagnetic contactor MC is energized. , becomes operational. Also,
Current detection circuit DT detects the excitation current and turns on transistors Q ₄ and Q ₅ . As a result, the s line → diode D ₉ → light emitting diode LED ₁ → dedicated line L ₁ → diode D ₈ → resistors R ₈ , R ₉ → light emitting part of photocouplers PC ₁ , PC ₂ → the other half wave on the r line path. When the power is applied, the light receiving part of the photocoupler PC ₂ is turned on, the indicator light circuit DP lights up the operation indicator lamp RL, and the light emitting diode LED ₁ also lights up.

Next, when external contact Z is turned off, power to the light emitting part of photocoupler PC ₅ is stopped, and the photocoupler
When the light receiving part of PC ₅ is turned off, the transistor Q ₇ ,
Q ₈ is turned off, relay X ₁ is no longer energized, and
Contact _x1 is turned off, and the magnetic contactor MC becomes de-energized, and the operation is stopped. Furthermore, by eliminating the excitation current, transistors Q ₄ and Q ₅
is turned off, power to the light emitting part of photocoupler PC ₂ is stopped, the light receiving part of photocoupler PC ₂ is turned off, and the indicator light circuit DP turns off the operation indicator lamp RL, turns on the stop indicator lamp GL, and starts emitting light. Diode LED ₁ also turns off.

During operation with the external contact Z turned on, when the thermal relay trips and the contact tm switches to the normally open side, the excitation of the electromagnetic contactor MC is stopped and the operation is stopped. Furthermore, as the excitation current disappears, transistors Q ₄ and Q ₅ are turned off, power to the light emitting part of the photocoupler PC ₂ is stopped, the light receiving part is turned off, and the indicator lamp circuit DP turns off the operation indicator lamp RL. Turn off the light. Furthermore, the photocoupler
Turn on power to PC _4A and PC _4B to turn on their light receiving sections. As a result, s line → Fritzker circuit FC →
Transistor Q ₆ → Diode D ₁₀ → Light emitting diode LED ₁ → Dedicated line L ₁ → Diode D ₈ → Resistor R ₈ , R ₉
→ Light emitting parts of photocouplers PC ₁ and PC ₂ → The r line is intermittently energized, and the indicator light circuit DP lights up the error indicator lamp OL. Also, by turning on the light receiving part of photocoupler PC _4B , the transistor
Turn off Q ₂ and inhibit energization of relay X ₁ .

After that, when the thermal relay is reset, the power to the light emitting parts of photocouplers PC _4A and PC _4B is stopped.
Those light receiving sections are turned off. As a result, the indicator light circuit DP turns off the abnormality indicator lamp OL and turns on the stop indicator lamp GL, and also turns off the transistor _Q2.
Turn on to release the prohibition of excitation of relay _X1 .

Next, press the off selection button, that is, in response to the off selection operation, turn off the hand selection switches SW ₁ and SW ₄ .
A case will be described in which the off selection switches SW ₂ and SW ₅ are turned ON and the remote selection switch SW ₆ is turned OFF.
In this case, by turning off selection switch SW ₅ ON, r
Line → Diode D ₂₁ → Resistor R ₃₄ → Light emitting diode LED ₄ → Off selection switch SW ₅ → Half-wave energization is applied through the s line path, and light emitting diode LED ₄ lights up to display the "off" status. Also, at this time, the local selection switch SW ₄ and the remote selection switch
Since both SW ₆ are off, transistor Q ₁₁
There is a resistance between the base and emitter of the rs voltage.
A sufficiently high base voltage divided by R ₃₃ , R ₃₂ , and R ₃₁ is applied to the transistor.
Q ₁₁ is turned on, and even if the off selection switch SW ₂ is off, it will be in the "off" state.

In this state, relay _X1 is not energized at all even if switch PB _ON1 is turned on. Also, when external contact Z is turned on, transistor Q ₈ is turned on and the r line → transistor Q ₈ → diode D ₅ → resistor R ₂ → relay X ₁ → transistor Q ₂ →
Diode D ₄ -> energized through the s line path, but r line -> transistor Q ₈ -> diode D ₅ -> light emitting part of photocoupler PC ₃ -> light emitting diode LED ₁ -> dedicated line L ₁ -> off selection switch SW ₂ -> resistance
R ₇ → Diode D ₆ → One-side half-wave current is applied in the path of the s line, the light receiving part of photocoupler PC ₃ is turned on, transistor Q ₃ is turned on, transistor Q ₂ is turned off, and excitation of relay X ₁ is prohibited. As a result, the stop indicator lamp GL lights up.

_C1 is a capacitor that delays the excitation stop of relay _X1 for a certain period of time, _D11 is a diode, _DB1 is a diode bridge, and _C4 and _C5 are capacitors.

In this way, this embodiment has an off selection switch.
Transistor Q ₁₁ is connected in parallel with SW ₂ , and when both local selection switch SW ₄ and remote selection switch SW ₆ are OFF, transistor Q ₁₁ is turned on, and either local selection switch SW ₄ or remote selection switch SW ₆ is turned on. The circuit is configured so that transistor _Q11 is turned off when either one is turned on, so
If neither "Near" nor "Far" is set, the switch will always be set to "Off" regardless of whether it is set to "Off" by off selection switch SW _2.
, and the "off" state can be prioritized. Therefore, even if the off selection switch SW ₂ cannot be turned on due to a malfunction of the off selection switch SW ₂ , or if the off selection operation is insufficient, the "off" switch will always be turned on.
The system is in this state and will not operate unexpectedly during inspections, improving safety. Also, hand selection switch SW ₄ , off selection switch SW ₅
The light emitting diodes LED ₃ to _{LED 5} light up in response to turning on the remote selection switch SW ₆ , so you can see at a glance which state the light emitting diodes are currently in, and even if the operation of each selection button is insufficient, the light emitting diodes
This can be determined by the fact that LED ₃ to _{LED 5} do not light up. In addition, a transistor is connected in parallel with the off selection switch _SW2 .
Since the _Q11s are connected in parallel, even if one fails, the other can be turned off, ensuring high reliability.

FIG. 2 shows a circuit diagram of a lid block BK ₂₃ , which is a modified circuit example of the lid block BK ₂₂ in _FIG . It is something that Specifically, transistor Q ₁ is connected to the light receiving part of photocoupler PC ₁ .
Rather than controlling the transistor Q 1 directly, the on/off of the transistor Q _{1 is controlled via the transistor Q 1 ′ ,} and when the light receiving section of the photocoupler PC ₁ is off, the transistor Q ₁ ′ is turned on. When the transistor Q ₁ is turned off and the light receiving section of the photocoupler PC ₁ is turned on, the transistor Q ₁ ' is turned off and the transistor Q ₁ is turned on. R36,
R37 is a resistor.

A second embodiment of the invention will be described based on FIG. This control device uses a lid block BK ₂₄ in place of the lid block BK ₂₂ shown in FIG. 1B.

In the circuit shown in Figure 3, pressing the hand selection button turns on hand selection switches SW ₁ and SW ₄ , turns off hand selection switch SW ₇ , and turns off selection switches SW ₂ and SW ₅ .
If the remote selection switch SW ₃ and SW ₆ are turned OFF and the remote selection switch SW ₈ is turned ON, the light emitting diode is turned on by turning the local selection switch SW ₄ ON.
LED ₃ lights up to indicate the "hand" status, and hand selection switch SW ₇ turns OFF and off selection switch
When SW ₂ is turned OFF, the "off" state is canceled, and when the hand selection switch SW ₁ is turned on, the "hand" state is entered.

Also, press the remote selection button to switch to the local selection switch.
Turn off SW ₁ and SW ₄ , and turn off hand selection switch SW ₇ .
ON, OFF selection switch SW ₂ , SW ₅ , OFF remote selection switch SW ₃ , SW ₆ , ON remote selection switch
If SW ₈ is turned OFF, the remote selection switch
When SW ₆ is turned ON, light emitting diode LED ₅ lights up to display the "far" status, and the far selection switch is turned on.
When SW ₈ is turned OFF and off selection switch SW ₂ is turned OFF, the "off" state is canceled and the hand selection switch is turned off.
Since SW ₁ is OFF, it is in a "distant" state.

Furthermore, press the OFF selection button to switch the hand selection switch.
Turn off SW ₁ and SW ₄ , and turn off hand selection switch SW ₇ .
ON, off selection switch SW ₂ and SW ₅ are ON, far selection switch SW ₃ and SW ₆ are OFF, and far selection switch SW ₈ is ON, off selection switch SW ₅ is
When turned on, light emitting diode LED ₄ lights up and turns off.
The status is displayed, and if the off selection switch SW ₂ is ON, it will be in the "off" state.

Other operations are the same as those shown in FIG. 1B.

The effects of this embodiment are similar to those of the first embodiment.

A third embodiment of the invention will be described based on FIG. 4. This control device connects the photocouplers PC ₁ and PC ₂ in FIG. 3 to the relay RyZ and its contacts z ₁ ,
_z2 , and the other configurations and effects are the same as in the second embodiment.

A fourth embodiment of this invention will be described based on FIG. This control device includes a transistor Q ₁₂ and a local selection switch in place of the local selection switch SW ₇ and the remote selection switch SW ₈ in FIG.
SW ₉ , remote selection switch SW ₁₀ , diode D ₂₂ ,
A circuit consisting of D ₂₃ , resistors R ₄₀ and R ₄₁ is connected in parallel to a series circuit consisting of an on-off selection switch SW ₁ , a diode D ₁₂ and a resistor R ₆ .

In this circuit, when either the local selection switch SW ₉ or the remote selection switch SW ₁₀ is turned on, the transistor Q ₁₂ is turned off, and both the local selection switch SW ₉ or the remote selection switch SW ₁₀ are turned off. At this time, the transistor _Q12 is turned on and is preferentially turned off regardless of whether the off selection switch _SW2 is on or off.

Other configurations and effects are the same as those in FIG. 4.

Note that the external contact Z may not only be one that turns on and off automatically, such as the output contact of a floatless relay, but also one that can be turned on and off manually.
In addition, it operates by the operation switch and recovery switch.
The relay contact to be restored may be set to external setting Z.

〔Effect of the invention〕

In the control device of the present invention, a switch that opens in response to a local selection operation and a remote selection operation is provided in parallel with the off selection switch, so that only when the off selection device is performed and the off selection switch is turned on. In addition, the "off" state can be set even when neither the local selection operation nor the remote selection operation is performed, and safety can be improved by giving priority to the "off" state.

[Brief explanation of the drawing]

1A and 1B are circuit diagrams of a first embodiment of the present invention, FIG. 2 is a circuit diagram of a modification thereof, and FIG. 3 is a circuit diagram of a lid block according to a second embodiment of the present invention. 4
FIG. 5 is a circuit diagram of a lid block according to a third embodiment of the present invention, FIG. 5 is a circuit diagram of a lid block according to a fourth embodiment of the invention, and FIG. 6 is a circuit diagram of a lid block according to a conventional example. It is. r, s...Power line, PB _ON1 ...Switch (one-way energizing type hand switch), _D1 ...Diode (one-way energizing type hand switch), DP...Indicator circuit (other direction energizing type indicator) , PC ₂ ... Photocoupler (other-way conduction type indicator), D ₁₂ , D ₆ ... Diode (first and second one-way conduction type directional element), SW ₁ ... Hand-held selection switch, SW ₂ ... ...Off selection switch, SW ₃ ...Remote selection switch, BK ₂₂
... Lid block (first block), X ₁ ... Relay (main relay), Q ₂ ... Transistor (normally closed contact), D ₃ ... Diode (third unidirectional conduction type directional element), PC ₃ ...Photocoupler (auxiliary relay),
Z……External contact (one-way conduction type external contact), Q ₂ …
…Transistor (one-way conduction type external contact), D ₅ …
...Diode (unidirectional current-carrying external contact), x ₁ ...
Contact (normally open contact with power in the other direction), Q ₅ ...Transistor (normally open contact with power in the other direction), D ₉ ...Diode (normally open contact with power in the other direction), BK ₁ ...Body block (second Block), L ₁ ...Dedicated line.

Claims (1)

[Scope of Claims] 1. A one-way energizing type hand switch D ₁ , PB _ON1 whose one end is connected to one power line r, and an other-way energizing type display device whose one end is connected to the one power line r.
PC ₂ , DP, first and second one-way energizing type directional elements D ₁₂ , D ₆ each having one end connected to the other power supply line s, and the one-way energizing type hand switch D ₁ , PB _ON1 . One end is connected to the other end and the other end of the first one-way energizing type directional element _D12 , and the other end of the other direction energizing type indicator _PC2 , DP and the second one-way energizing type directional element A hand selection switch whose other end is connected to the other end of element D ₆ and which turns on in response to a hand selection operation and turns off in response to an off selection operation and a remote selection operation.
It is inserted into the path leading from SW ₁ and the other power supply line s to the other end of the hand selection switch SW ₁ via the second unidirectional energizing type directional element D ₆ and responds to an off selection operation. an off selection switch SW ₂ that is turned on in response to the local selection operation and a remote selection operation _, and turned off in response to the local selection operation and the remote selection operation; _The first block BK ₂₂ is composed of _a switch Q ₁₁ that opens in response _to and a third unidirectional current-carrying type directional element whose one end is connected to the other end of the series circuit of the normally closed contact _Q2 .
D ₃ , an auxiliary relay PC ₃ connected in parallel to the third one-way energizing type directional element D ₃ and driving the normally closed contact Q ₂ to open, the one power supply line r and the main relay X ₁ and a unidirectional current-carrying external contact D ₅ connected between the other end of the series circuit of the normally closed contact Q ₂ ,
Q ₈ : Z, the other power supply line s and the third
Normally open contacts Q ₅ , Q ₄ are connected between the other end of the directional element D ₃ and the other end _of the directional element D 3 is driven to close by the main relay X ₁ . A second block BK ₁ is configured, and the other ends of the hand selection switch SW ₁ and the off selection switch SW ₂ are connected to the other end of the third one-way conduction type directional element D ₃ by a dedicated line L ₁ . Control device. 2. The switch is turned on in response to a local selection operation and turned off in response to an off selection operation and a remote selection operation, respectively, and in response to a remote selection operation. Claim 1: The second switch is turned on and turned off in response to a hand selection operation and an off selection operation, respectively.
Control device as described in section. 3. The switch is turned off in response to a local selection operation, and a first off priority switch is turned on in response to an off selection operation and a remote selection operation, and is turned off in response to a remote selection operation. 2. The control device according to claim 1, wherein the control device comprises a series circuit comprising: a second switch for switching off priority, which is turned on in response to a hand selection operation and an off selection operation, respectively.