JP3251516B2 - Disaster prevention system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a disaster prevention system for controlling a smoke control device in association with a fire signal indicating a fire detection.

[0002]

2. Description of the Related Art Conventionally, there has been a disaster prevention system which controls a plurality of smoke control devices in association with detection of a fire by a fire alarm (including a fire detector and a transmitter). In such a disaster prevention system, generally, interlocking data indicating a fire sensor and a control terminal of a smoke prevention device that are interlocked is stored in a storage device, and when a fire signal is input from the fire sensor, A control signal is output to the corresponding control terminal based on the interlocking data to control the smoke prevention equipment. In addition, in such a disaster prevention system, a collective non-interlocking switch that non-interlocks all together so that the smoke prevention equipment does not start even if a fire signal is output from the fire detector at system startup, maintenance, etc. Is provided.

[0003]

The above-mentioned collective non-interlocking switch can set all of the smoke-prevention devices to non-interlocking at a time, so that excessive control of the smoke-prevention device due to malfunction can be prevented. At the time of system adjustment at the time of system start-up or the like, it may be better to individually set the smoke evacuating apparatus to a non-interlocking state. In the conventional disaster prevention system described above, smoke control devices, such as fire dampers, fire shutters, fire doors, etc., which are controlled in response to fire detectors that have been activated (detected fire phenomena), are not controlled by district or type. It could not be set to interlock. In addition, although non-interlocking switches such as hydrant non-interlocking and transfer stop are provided, these cannot be individually set to the non-interlocking state.

According to the present invention, in a disaster prevention system in which a plurality of smoke prevention devices are controlled in conjunction with the detection of a fire, the interlocking state can be individually set to non-interlocking, which is convenient when adjusting the system. The purpose is to provide a good disaster prevention system.

[0005]

According to a first aspect of the present invention, there is provided a fire sensor for detecting a fire and outputting a fire signal. A plurality of smoke elimination devices, and a receiver that receives a signal from the fire detector and can transmit a signal to the smoke elimination device side, and is predetermined in association with the fire signal of the fire detector. Disaster prevention system that controls the operation of
In addition , the disaster prevention system includes a batch non-interlocking setting unit that sets the operation control of the smoke prevention device to a non-interlocking state for all the smoke prevention devices collectively by an operation input .
Is set in advance to operate in conjunction with the operation input.
The operation control of the order was the Bohai smoke devices, both as being individually settable to a non-interlocking state for a given Bohai smoke equipment
Further, an individual non-interlocking setting means capable of canceling the setting is provided.

According to the first aspect of the present invention, the collective non-interlocking setting means can set the operation control based on the fire signal of all of the smoke control devices so as not to be collectively interlocked, so that the system is started up. At the time of adjusting the system or when the system is adjusted, it is possible to prevent the smoke detector from malfunctioning due to a malfunction of the fire detector (a fire signal is output when the fire is not a fire). Further, when it is better not to link only to the control of a predetermined smoke prevention device with a fire signal when starting up the system or adjusting the system, it is possible to make detailed settings by using the individual non-linkage setting means. .

[0007] Here, the smoke exhaust equipment includes, for example, a smoke exhaust damper, a smoke exhaust fan, a hanging wall, a fireproof damper, a fireproof shutter, a fireproof door and the like. The predetermined smoke elimination device that can be individually set to the non-interlocked state does not need to be one smoke elimination device, but a plurality of smoke elimination devices are united (one setting unit).
It is also possible to set individually. As an example of the unit (setting unit), among multiple smoke prevention devices,
Any category or condition, such as a unit provided in a predetermined area (one set unit) or a predetermined type of smoke prevention equipment (one set unit), was created. The number of groups (setting units) that can be individually set need not be one, but may be plural.

According to a second aspect of the present invention, in the disaster prevention system according to the first aspect, the plurality of smoke evacuating devices are provided in a plurality of areas, and the individual non-interlocking setting means includes an evacuating device based on the fire signal. The operation control of the smoke equipment can be set to the non-interlocking state for each area where the smoke prevention equipment is provided.

According to the second aspect of the present invention, the setting of interlocking / non-interlocking based on the fire signal of the smoke control device can be performed for each area where the smoke control device is provided.
For example, it is convenient when the system is adjusted for each area.

According to a third aspect of the present invention, there is provided the disaster prevention system according to the first or second aspect, wherein there are a plurality of types of the smoke prevention devices, and the individual non-interlocked setting means is based on the fire signal. Operation control can be set to a non-interlocking state for each type of smoke prevention equipment.

According to the third aspect of the invention, the setting of interlocking / non-interlocking based on the fire signal of the smoke control device can be performed for each type of the smoke control device. It is convenient at the time, especially when adjusting a particular type of smoke control device.

According to a fourth aspect of the present invention, in the disaster prevention system according to any one of the first to third aspects, any of the smoke control devices based on the fire signal is controlled. The operation control can be set to the non-interlocking state by both the collective non-interlocking setting means and the individual non-interlocking setting means, and the non-interlocking state can be set in one of the collective non-interlocking setting means and the individual non-interlocking setting means. The operation control for the arbitrary smoke prevention device is not performed when the setting of (1) is performed.
Disaster prevention system according to the paragraph.

According to the fourth aspect of the invention, the setting of the non-interlocking state for an arbitrary smoke prevention device can be performed by both the collective non-interlocking setting means and the individual non-interlocking setting means. By setting, a double non-interlocking state can be set. Therefore, by turning on / off the setting by the collective non-interlocking setting means in a state where the specific smoke preventing devices are individually set to the non-interlocking state, the collective non-interlocking state of all the smoke preventing devices is set to the specified state. Can be easily switched to the non-interlocking state of only the smoke prevention device. By this switching, for example, when adjusting the system, it is possible to easily respond to a request that a specific smoke prevention device is always in a non-interlocking state and other smoke prevention devices are desired to be in a non-interlocking state after a while.

According to a fifth aspect of the present invention, in the disaster prevention system according to any one of the first to fourth aspects, a display unit for displaying a setting state of the batch non-interlocking setting means is provided,
The display unit performs a display that can identify whether or not there is a non-interlocking state set by the individual non-interlocking setting unit when the non-interlocking state setting is not performed by the collective non-interlocking setting unit. The configuration was adopted.

According to the fifth aspect of the present invention, when the setting of the collective non-interlocking state by the collective non-interlocking setting means is canceled by the display on the display unit, the setting of the individual non-interlocking state still remains. Can be identified. Therefore, for example, when the adjustment of the system is completed and the setting of all the non-interlocked states is canceled, it is possible to confirm the sure cancellation. That is, although there is the setting of the non-interlocking state by the individual non-interlocking setting means, the misunderstanding that all the non-interlocking states have been released can be prevented by simply canceling the setting of the collective non-interlocking setting means.

Here, the display unit can be composed of, for example, one indicator light (for example, a light emitting diode, a light bulb, an electric light, or the like). In addition, a 7-segment display, a liquid crystal display, a CRT display, or the like can be used. Image display may be used. The above-described identifiable display can be realized if three types of display can be performed. For example, when one display lamp is used as the display unit, the display can be realized by lighting, blinking, and turning off. In addition, by providing the display unit near the operation unit (for example, a switch) of the collective non-interlocking setting unit, the display can be confirmed while performing the operation input, which is more effective.

According to a sixth aspect of the present invention, in the disaster prevention system according to any one of the first to fifth aspects, a display means for displaying a setting state of the individual non-interlocked setting means is provided, wherein the display means comprises: Whether the double non-interlocking state is set by the collective non-interlocking setting means and the individual non-interlocking setting means, or the non-interlocking state is set by either the batch non-interlocking setting means or the individual non-interlocking setting means The display is configured to identify whether the setting has been made.

According to the present invention, when the setting of the individual non-interlocking setting means is switched to the interlocking by the display of the display means, whether the setting is switched from the double setting to the single setting or the single setting. It is possible to identify whether the setting is released from. Further, when the setting of the individual non-interlocking setting unit is switched to the non-interlocking state, it is possible to identify whether the interlocking state is changed to the single non-interlocking state or the single setting is changed to the double setting. That is, when the setting of the individual non-interlocked state is switched, it can be determined whether or not the setting is actually effective. Further, when changing the setting pattern by the individual non-interlocking setting means, the setting pattern is changed once by interposing the collective non-interlocking state by the collective non-interlocking setting means during the change, and thereafter, the collective non-interlocking setting means is changed. There is a possibility of changing the setting pattern by unsetting the setting, so that the changed setting pattern can be made valid all the time. However, in such a case, the setting change operation is performed in a state where the intervention of the batch non-interlocking setting means is reliably recognized. Can be performed.

Here, the display means can be constituted by, for example, displaying an image on a liquid crystal display or a CRT display, or by using a plurality of display lamps. The above-mentioned identifiable display may be identifiable by, for example, a color or a display pattern, or may be identifiable by a character display, and can be realized in various forms.

According to a seventh aspect of the present invention, in the disaster prevention system according to the sixth aspect, the individual non-interlocking setting means non-interlocks the operation control of the smoke prevention equipment based on the fire signal for each predetermined setting unit. The display means is provided with a plurality of display windows corresponding to each of the predetermined setting units, and each of these display windows is provided with the predetermined setting corresponding to each display window. A setting state for the unit is displayed, and an operation input can be performed by touch operation on each of these display windows, and a touch operation input for setting the non-interlocking state of the predetermined setting unit corresponding to each display window. Means were provided.

According to the seventh aspect of the present invention, the entire image of the individual setting in the individual non-interlocking state can be collectively recognized by the plurality of display windows provided in the display means. Further, the touch operation input means is provided in the display window, so that an operation input without any mistake can be made when changing the setting. That is, the entire setting unit can be reliably recognized and operated, and therefore, the number of setting units that can be individually set can be increased. The number of display windows is
Since it can be changed by rewriting the control program for image display, it is possible to easily cope with a change in a fire detector or a smoke prevention device connected to the system.

Here, the display window can be constituted by, for example, an image display of a liquid crystal display or a cathode ray tube display, and in addition, any type of display window can be constituted by a transparent panel or the like. It may be something.
The touch operation input means is a known technique.

According to an eighth aspect of the present invention, in the disaster prevention system according to any one of the first to seventh aspects, when the system is started up, the setting of the collective non- interlocking setting means is set to the non-interlocking state and the individual non-interlocking state is set. The configuration is such that all smoke control devices for which the setting of the interlock setting means can be set are not interlocked.

According to the present invention, it is possible to prevent the malfunction of the fire detector (e.g., a fire signal is output even though it is not a fire) at the time of starting the system, thereby preventing the control of the smoke control device. I can do it.

According to a ninth aspect of the present invention, in the disaster prevention system according to any one of the first to eighth aspects, the setting states of the collective non- interlocking setting means and the individual non-interlocking setting means are changed. It is characterized by comprising setting state storage means for storing.

According to the invention of claim 9, wherein, the setting state of the non-interlocking setting means and individual unsynchronized setting means collectively set state storage means is stored, for example, non-interlocked together, such as during adjustment of the system Even if the power of the setting unit or the individual non-interlocking setting unit is turned off, the setting state can be restored when the power is turned on again.

Here, the setting state storage means can be constituted by, for example, a non-volatile memory or the like. If the power-off time is not long, a static RA is used.
It can also be configured with M (Random Access Memory).

According to a tenth aspect of the present invention, in the disaster prevention system according to the ninth aspect, when the system is restarted, the setting of the collective non- interlocking setting means and the individual non-interlocking setting means is performed.
The setting state is stored in the setting state storage means.

According to the tenth aspect, even when the power of the system is once turned off and then turned on again, for example, at the time of system adjustment, the setting of interlocking / non-interlocking is the same as before the power was turned off. This is convenient because there is no need to reset it from the beginning. In addition, when the power is turned on again, the setting of the non-interlocked state does not change to the setting of the interlocked state. Therefore, when the power is turned on again, the fire detector malfunctions (fire signal is output even though it is not a fire). It is possible to prevent the control of smoke elimination equipment.

According to an eleventh aspect of the present invention, in the disaster prevention system according to the ninth aspect, when the system is restarted, the setting of the collective non-interlocking setting means and the individual non-interlocking setting means is performed.
A configuration is provided in which a first control state setting means is provided which can select and set whether to set all to a non-interlocked state or to a setting state stored in the setting state storage means.

According to the eleventh aspect of the present invention, the first
The effect of the invention according to claim 10 is achieved by setting the control state setting means to the latter, and the power supply is turned on again by setting the first control state setting means to the former. In this case, it is possible to reliably prevent the control of the smoke elimination device due to a malfunction of the fire detector (for example, a fire signal is output even though it is not a fire). Therefore, when the system state when the power is turned on again is not much different from when the power is turned off, and when there is a possibility that the state may be significantly different from when the power is turned off, the first state is set.
Can be handled by changing the setting of the control state setting means.

Here, the first control state setting means can be configured in various forms. However, in order to prevent the control state from being changed when the power is turned on again, the first control state setting means can be easily set. It is effective to provide it in a place where it cannot be changed.

According to a twelfth aspect of the present invention, in the disaster prevention system according to the eleventh aspect, when the system is restarted, the setting of the collective non-interlocking setting means is set to the non-interlocking state, and the setting of the individual non-interlocking setting means is changed to the setting of the individual non-interlocking setting means. A configuration is provided in which second control state setting means is provided which can be selectively set to each of the setting states stored in the setting state storage means.

According to the twelfth aspect of the present invention, in addition to the operation and effect of the eleventh aspect of the present invention, by setting as described above by the second control state setting means, there can be various setting states. Since the non-interlocking setting means is the same as before the power is turned off, there is no need to reset the settings from the beginning, and it is convenient. Because of the interlocking state, it is possible to reliably prevent the control of the smoke control device due to the malfunction of the fire detector when the power is turned on again.

Here, the second control state setting means comprises a first control state setting means.
Can be configured in various forms, as with the control state setting means, but it is effective to set it in a place where the setting cannot be changed easily in order to prevent the control state when the power is turned on again It is a target.

[0036]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a disaster prevention system according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a configuration diagram showing an entire disaster prevention system 1 according to an embodiment of the present invention.

In the disaster prevention system 1 according to the embodiment of the present invention, the fire detectors S1, S2,... And the smoke emission devices ER1, E are connected to the receiver RE via a signal line (transmission line) 3.
R2... Are connected. Further, the receiver RE includes a transfer signal SIG to a bell or an elevator (not shown).
Is connected.

The fire detectors S1, S2,... And the smoke suppression devices ER1, ER2,... Are respectively arranged in a plurality of areas, and the fire detectors S1, S2,. The polling communication with the RE is performed using the receiver RE as a host station. The smoke elimination devices ER1, ER2 ... prevent the spread of fire and smoke,
Also, it is for discharging the filled smoke to the outside of the room, for example, a smoke exhaust damper, a smoke exhaust fan, a hanging wall, a fire damper,
Includes fire shutters, fire doors, etc. Are connected to a signal line 3 via a control terminal (not shown), and these control terminals receive the smoke prevention devices ER1, ER1, ER1,
ER2... Are individually controlled.

FIG. 2 is a plan view showing the operation panel of the receiver RE, and FIG. 3 is a block diagram showing the configuration of the receiver RE. As shown in FIG. 2, an operation panel 50 provided on the front side of the receiver RE is provided with a district display section 51 having a 7-segment display, a liquid crystal display section 52, a fire confirmation switch 53, and various switches. Main operation display section 6
0, a printer 62, a sound device 63, and the like.

The main operation display section 60 includes an operation switch 54.
..., 55 ..., transfer stop switch 56, fire hydrant non-interlocking switch 57, first batch non-interlocking switch SW1, and
An indicator light 59 composed of a plurality of electric lights is provided. First
Bulk breakaway switch SW1 of, those according to the present invention, on / in Off that, collectively fire detector S1, S2 ... All Bohai smoke devices based on the fire signal ER1, ER 2 ... operational control of Then, the state is switched to the non-linked state / linked state. The transfer stop switch 56 and the fire hydrant non-interlock switch 57 set the transmission of the transfer signal SIG based on the fire signal and the operation control of the hydrant collectively to the non-interlock state.

The fire confirmation switch 53, the operation switches 54, 55,..., The transmission stop switch 56, the hydrant non-interlocking switch 57, and the first batch non-interlocking switch S
Inside the W1, LEDs (light emitting diodes) are arranged, respectively, to turn on / off the switch setting state (on / off).
It is shown as off. The LED in the first collective non-interlocking switch SW1 has the setting state of the first collective non-interlocking switch SW1 turned off, and sets the individual non-interlocking state by the individual non-interlocking switches 501 to 516 described below. When there is, a blinking display is performed to indicate whether or not the individual non-interlocking state is set.

The liquid crystal display 52 includes a liquid crystal display 52.
A and touch panel 52 capable of inputting signals by touch operation
B. A display window corresponding to various operation keys is displayed on the liquid crystal display 52A as an image, and a signal corresponding to the operation key is input from the touch panel 52B by touching the display window.

For example, as shown in FIG. 4, which is an example of a display image on the liquid crystal display unit 52, the liquid crystal display unit 52 displays a date and time, a switch call key 520, a screen copy key 521, and a print stop key 522. , A sound stop key 523, a district sound stop key 524, a return key 525, a menu key 526, a screen erase key 527, and other various control keys, and other operation keys 529, 529... Are displayed. By performing a predetermined key operation using a key or an operation key (for example, turning on a switch call key 520), a “protection” for individually setting the smoke suppression devices ER1, ER2,. The display screen (FIG. 4) of "Smoke emission non-interlocking" is called up.

On the display screen of "non-linked smoke emission", "non-linked smoke emission" indicating that the screen mode is set is displayed, and the individual non-linked switches 501 to 51 are displayed.
6 is displayed. These individual non-interlocking switches 501 to 516 are a feature of the present invention, and the smoke prevention devices ER1, ER2,.
Of these, the operation control based on the fire signal is set individually in a non-interlocked state for each predetermined setting unit. For example, by turning on / off the individual non-interlocking switch 501, the operation control (operation control based on a fire signal) of the smoke control devices ER1, ER2, and ER3 corresponding to the switch is individually set / released to the non-interlocking state. It is supposed to be.

These individual non-interlocking switches 501 to 516
The setting units that can be individually set to the non-interlocking state include setting units that are classified according to the arrangement area of the smoke suppression devices ER1, ER2,... And setting units that are classified according to the types of the smoke suppression devices ER1, ER2. and so on. For example, smoke suppression equipment ER
1, ER2, ER3, ER4, ER5, ER6, ER
Assuming that 7, ER8 are respectively arranged in the areas A to G, the individual non-interlocking switch 501 corresponds to the smoke control devices ER1, ER2, ER3 arranged in the area A, and the individual non-interlocking switch 502 corresponds to the area B. Smoke prevention equipment ER4 arranged
In response to the above, individual non-interlocking switches 501 to 50
7 correspond to the smoke elimination devices ER1, ER2,... Also, for example, the smoke elimination device ER
1, ER2, ER3, ER4, ER5, ER6, ER
Assuming that there are three types of H, J, and ER8 (for example, fire protection damper, fire protection shutter, fire protection damper, etc.), the individual non-interlocking switch 508 sets the H type smoke prevention equipment ER.
1, non-interlocking switch 50 corresponding to ER4, ER7
9 corresponds to the type I smoke-control devices ER2, ER5, etc., and the individual non-interlocking switches 508 to 510 correspond to the smoke-control devices ER1, ER2,.

The setting units that can be individually set to the non-interlocked state are not limited to those specifically described above, and any categories and conditions classified as the setting units may be used. The smoke appliances ER1, ER2,... May be individually set in a non-interlocked state. Further, the type of the smoke prevention device is not limited to the above, and for example, the type of the model may be the type of the smoke prevention device. In addition, the same smoke prevention device can be set so as to be included over a plurality of setting units.

These individual non-interlocking switches (display windows) 5
01 to 516 correspond to the respective smoke control devices ER1 and ER.
.. Are displayed. When the double non-interlocking state is set by the setting of the first batch non-interlocking switch SW1, the following display for identifying the double setting state is performed. ing.

The following table shows the setting states of the first collective non-interlocking switch SW1 and the individual non-interlocking switches 501 to 516, and the LED in the first collective non-interlocking switch SW1.
5 shows the correspondence between the display contents of the display windows of the individual non-interlocking switches 501 to 516.

[Table 1] In the table, in the column of “Individual non-linked screen (monochrome)”, when the display of the liquid crystal display 52A is monochrome,
The display contents of the display windows of the individual non-interlocking switches 501 to 516 are shown. In the column of “individual non-interlocking screen (color)”, each individual non-interlocking switch 501 when the display of the liquid crystal display 52A is color is displayed. The display contents of the display windows 516 to 516 are shown. “Normal” refers to, for example, the background color, and “reverse” refers to the reversal of the background color.

As shown in FIG. 3, a main control circuit 20 for performing main control of the receiver RE and an operation display control circuit 3 for mainly controlling the main operation display section 60 are provided inside the receiver RE.
0, a liquid crystal control circuit 40 for controlling the liquid crystal display unit 52, and the like. The liquid crystal control circuit 40 is connected to the operation display control circuit 30 via interfaces (I / Fs) 37 and 44, and the main control circuit 20 is connected to the operation display control circuit 30 and the liquid crystal control circuit 30 via a dual port RAM 38. It is connected to the control circuit 40 side.

Further, a second batch non-interlocking switch SW2 which is a feature of the present invention is provided inside the receiver RE. The input state of the second collective non-interlocking switch SW2 is read by the operation display control circuit 30 when the power is turned on, and determines, for example, a control state when the power is turned on, which will be described later. This second batch non-interlocking switch S
W2 is used, for example, by a maintenance manager of the receiver RE to perform a setting operation, and an operator (general person) of the receiver RE
It is not easy to operate.

The main control circuit 20 has a main CPU (Ce
ntral Processing Unit) 21, 1st ROM (Read Onl)
y Memory) 22, 1st RAM (Random Access Memory)
23, a DIP switch 24, a transfer interface (I / F) 25, a transmission interface (I / F) 26, and the like, which are features of the present invention, are connected to a data bus 27, respectively. The first RAM 23 is a static RAM or an EAROM (Electrically Alterable
ROM) and the like, and the stored state is maintained at least for a predetermined period even if the power is turned off. The signal line 3 is connected to the transmission interface 26.

The main CPU 21 executes control processing based on a control program and control data stored in the first ROM 22, using the first RAM 23 as a work area. The control processing mainly includes the output of a transfer signal from the transfer interface 25 and the fire detectors S1, S2,.
And communication control with the smoke control devices ER1, ER2,..., Reading and writing data from the dual port RAM 38, and the like. The above communication is performed via the transmission interface 26.

The DIP switch 24 is connected to the main CPU 2
1 to set a control state, for example, a power-on control state described later. The control state is provided in a hidden place of the receiver RE (for example, a concave portion is provided on the back of the receiver RE, The dip switch 24 is arranged inside and the lid is closed). The DIP switch 24 is connected to, for example, the receiver R
The setting is performed by the maintenance manager of E, and is not easily operated by the operator (general person) of the receiver RE.

The operation display control circuit 30 includes an operation display C
PU31, dual port RAM (DR) 38, 2nd R
The OM 32, the second RAM 33, and the interfaces 34 to 37 are connected to the data bus 39, respectively. To the interfaces 34 to 37, a first collective non-interlocking switch SW1 (including an LED in the switch), an indicator light 59, a second collective non-interlocking switch SW2, etc. provided on the operation panel 50 are connected. . FIG.
Although not shown, the operation display control circuit 30 includes a fire confirmation switch 53, operation switches 54,..., A transmission stop switch 56, a fire hydrant non-interlocking switch 57, a printer 62, a sound device 63, and the like. Is also connected.

The operation display CPU 31 includes a second RAM 33.
In the work area, the control process is executed based on the control program and control data stored in the second ROM 32. The control process mainly includes various operation switches (a first batch non-interlocking switch SW1, a second batch non-interlocking switch SW2, a fire confirmation switch 53, operation switches 54, 55, a transmission stop switch 56, Input control of the fire hydrant non-interlocking switch 57), operation control of LEDs in these various operation switches, operation control of the indicator lamp 59, control of the printer 62 and the sound device 63, input / output processing of data from the liquid crystal drive circuit 40, There is a process of writing data to the dual port RAM 38 and the like.

The liquid crystal control circuit 40 includes an LCD CPU 4
1, a third ROM 42, a third RAM 43, an LCD display output circuit 45, an LCD switch input circuit 46, and an interface 44 are connected to a data bus 47, respectively. The LCD display output circuit 45 outputs a display drive signal to the liquid crystal display 52A, and the LCD switch input circuit 46 converts a touch signal of the touch operation switch 52B into a predetermined signal.

The liquid crystal CPU 41 executes control processing based on a control program and control data stored in the third ROM 42, using the third RAM 43 as a work area. The control processing includes display control of the liquid crystal display 52A, input processing from the touch operation switch 52B, input / output processing of a signal with the operation display control circuit 30, and the like.

FIG. 5 shows a first batch non-interlocking switch SW
1 and a memory configuration diagram of the first RAM 23 showing a data storage portion storing the setting states of the individual non-interlocking switches 501 to 516. FIG. 6 shows the fire detectors S1, S2,. A memory configuration diagram of the first ROM 22 showing a data storage portion storing various information is shown in FIG. 7, and fire detectors S1, S2.
The other example of the memory configuration diagram of the first ROM 22 showing a data storage portion storing various information of 1, ER2...

As shown in FIG. 5, the first RAM 23 has
A memory area A1 for storing the setting state of the first collective non-interlocking switch SW1 is provided, and the first
Of the collective non-interlocking switch SW1 is stored. In the first RAM 23, an individual non-interlocking switch 50 is arranged alongside the memory area A1.
A series of memory areas A for storing setting states 1 to 516
, A3,... Are provided, and these memory areas A2, A3,.
The individual non-interlocking switches 501 to 516 that have been turned on
Is stored. The district information refers to each individual non-interlocking switch 501
513 are data indicating the areas that can be individually set to the non-interlocking state. The type information is the individual non-interlocking switch 51.
4 to 516 are data indicating the types of smoke prevention devices ER1, ER2,.

As shown in FIG. 6, the first ROM 22 stores
Fire detectors S1, S2 ... and smoke elimination devices S1, S2 ...
Memory areas A10 and A1 in which the data of
1, A12... Are provided. In the memory configuration of this embodiment, each of the fire detectors S1, S2, S3,.
And a series of memory areas A10, A11, A12
Are allocated, and these memory areas A10, A11,
A12 are configured to store data of the smoke control devices ER1, ER2,.

For example, as information of the fire detector S1, address data used in polling communication between the receiver RE and the fire detectors S1, S2,..., Type information indicating the type of the fire detector S1, and information of the fire detector S1 In the memory area A10, information on the installed area, interlocking data indicating which of the smoke elimination devices ER1, ER2,... Are to be interlocked when the fire detector S1 detects a fire is stored. Then, in the interlocked data, the interlocked smoke control devices ER1, E
As the data of R2, ER3, each smoke control device ER1, E
Address data used in the polling communication of R2, ER3, type information indicating the type of each of the smoke control devices ER1, ER2, ER3, and district information indicating the located district,
Each is stored. Other fire detectors S2, S3 ...
The same applies to.

As described above, the smoke control devices ER1, ER2,.
Information (address, type information, district information) is written in the interlocking data of the fire detectors S1, S2,... When ER1, ER2,... Individually determine whether or not the condition for making a non-interlocked state is satisfied, data read processing can be performed collectively.

The memory configuration for storing the data of the fire detectors S1, S2,... And the smoke elimination devices ER1, ER2, is not limited to the above, and may be a configuration as shown in FIG. That is, each of the fire detectors S1, S2,... And the smoke control devices ER1, ER2,.
"01H (hex)" to "05H (hex)"... ) Are assigned to correspond to the above, and the respective data of the fire detectors S1, S2... And the smoke elimination devices ER1, ER2... Are stored in these memory regions A20 to A25.

For example, in the memory area A20 corresponding to the address code "01H", data (type information, district information, interlocking data) of the fire detector S1 having the address code is stored, and the address code "02H" is stored. The data (type information, district information) of the smoke prevention equipment ER1 having the address code is stored in the memory area A21 corresponding to. The same applies to the other fire detectors S2, S3,. Note that the linked data here includes the linked smoke control devices ER1 and ER.
Only the identification data of ER2 and ER3 are stored. With such a memory configuration, the amount of data to be stored can be minimized.

The disaster prevention system 1 according to this embodiment is configured as described above, and normally performs the conventional fire monitoring. However, for example, when the system is started up or the system is adjusted, the first fire prevention system is used. Non-interlocking switches SW1 and SW
2 and the dip switch 24, and the operation of the individual non-interlocking switches 501 to 516 of the liquid crystal display unit 52, etc., set the operation control of the smoke elimination devices ER1, ER2. I can do it. Next, these operations will be described.

Normally, the main CPU 21 operates in the first R
The control program of the OM 22 is executed to receive signals from the plurality of fire detectors S1, S2,... And perform fire monitoring. When a fire signal is sent from any of the fire detectors S1, S2, etc. (for example, from the fire detector S1), the main CPU
21 is a C for operation display via a dual port RAM 38
The operation data is transmitted to the PU 31 and the operation display CPU 31
Outputs a signal to the district display section 51, the indicator lamp 59, the speaker 63, and the like of the operation panel 50 based on the operation data, and causes the district display section 51 to display in which district a fire has occurred, 59 is displayed to indicate that a fire has occurred, and a fire alarm is output from the speaker 63.

When a fire signal is sent, the main CP
U21 is the memory area A10, A11 of the first ROM 22.
The data of the fire detector S1 that has issued the fire signal is read out of {}, and the control signal is transmitted to the smoke elimination devices ER1, ER2} described in the interlocking data in the data. This control signal activates the smoke control devices ER1, ER2 #. However, when the main CPU 21 reads the data of the fire detector S1, the main CPU 21 reads the data of the memory area A1 of the first RAM 23 (where the setting data of the first batch non-interlocking switch SW1 is stored). If the data indicates the ON state, the control signal is not transmitted to the smoke control devices ER1, ER2 #. If the data in the memory area A1 indicates the OFF state, the data in the memory areas A2, A3 # (where the setting data of the individual non-interlocked switches 501 to 516 is stored) is read. The data is compared with the data (type information and district information) of the smoke control devices ER1 and ER2 # described in the above-mentioned interlocking data. As a result of this comparison, when the type information or the district information matches, the smoke control devices ER1 and ER2 having the matched type information or the district information.
No control signal is transmitted for ‥.

That is, the memory area A1 of the first RAM 23
(The setting data of the first collective non-interlocking switch SW1 is stored.) When the setting of the first collective non-interlocking switch SW1 is in the ON state, even if a fire signal is sent, all of the fire-prevention is performed. The operation of the smoke appliances ER1, ER2 # is not controlled, and the individual non-interlocking is performed by the data in the memory areas A2, A3 # of the first RAM 23 (setting data of the individual non-interlocking switches 501 to 516 are stored). The operation of the smoke prevention devices ER1 and ER2 # included in the setting units set to ON of the switches 501 to 516 is not individually controlled even if a fire signal is sent.

[0069], such as during adjustment of the system, if it is necessary to unsynchronized state Bohai smoke device ER1 based fire signal, ER2 ... operation control of a variety of patterns, first
Collective non-interlocking switch SW1 and liquid crystal display 52
The setting is performed by appropriately operating the individual non-interlocking switches 501 to 516.

The first batch non-interlocking switch SW1 is turned on /
When an off operation is performed, the operation signal is transmitted to the operation display CPU 31.
The operation display CPU 31 writes the operation data of the on / off operation in a predetermined memory area of the dual port RAM 38. The main CPU 21 sequentially reads the data in the dual port RAM 38 and writes the latest data indicating the on / off state of the first batch non-interlocking switch SW1 to the memory area A1 of the first RAM 23. By this writing, even if a fire signal is sent, it is set so that the operation control of all the smoke elimination devices ER1, ER2 # is not performed.

When the individual non-interlocking switches 501 to 516 are turned on / off, the operation signals are sent to the LCD CPU 41.
The LCD CPU 41 transmits this operation signal to the operation display CPU 31. When the operation signal is received by the operation display CPU 31, the operation display CPU 31 writes operation data of the ON / OFF operation of the individual non-interlocking switches 501 to 516 in a predetermined memory area of the dual port RAM 38. Main CPU 21 has dual port R
The data in the AM 38 is sequentially read, and the latest data (type information or district information) indicating the on / off state of the individual non-interlocking switches 501 to 516 is written in the memory areas A2, A3 # of the first RAM 23. By this writing, even if a fire signal is sent, predetermined smoke elimination devices ER1, ER2 ‥
Are set so that operation is not individually controlled.

Further, the first batch non-interlocking switch S
When the W1 or the individual non-interlocking switches 501 to 516 are operated, the operation display CPU 31
Data in AM38 (first batch non-interlocking switch SW1
And operation data of the individual non-interlocking switches 501 to 516, and outputs a predetermined display signal to the LED in the first batch non-interlocking switch SW1. At the same time, LCD
The LCD CPU 41 transmits predetermined data to the LCD display output circuit 45 based on the data. According to these output signals, the LED in the first collective non-interlocking switch SW1 and the display windows of the individual non-interlocking switches 501 to 516 display the first collective non-interlocking switch SW1 as shown in Table 1 or The display based on the setting state of the individual non-interlocking switches 501 to 516 is performed.

When the system is started, the first batch non-interlocking switch SW1 and the individual non-interlocking switches 501 to 516 are all turned on by the following control program. When the system power is turned on again, the following three types of states are set based on the setting states of the DIP switch 24 and the second collective non-interlocking switch SW2 in the receiver RE by the following control program. Start with either. That is, the DIP switch 24 and the second collective non-interlocking switch SW2 constitute the first and second control state setting means, which is a feature of the present invention.

FIG. 8 shows a main control circuit 2 of the receiver RE.
FIG. 9 shows a part of a flowchart of a main control process at the time of system startup performed at 0 and FIG. 9 shows a part of a flowchart of a main control process at the time of system restart performed by the main control circuit 20 of the receiver RE. .

When the power is turned on to the receiver RE, first,
The main control circuit 20 is operated, and the main CPU 21 performs the setting processing of steps S1 and S2 # in FIG.
The setting processing of steps S11 and S12 # in FIG. 9 is performed. The branch to shift to these two setting processes is, for example,
Based on the storage state of the first RAM 23, whether the power is turned on for the first time or for the second time is determined and determined.

That is, when the system is started up (ie,
When the power is turned on for the first time after setting the system),
The process branches to the setting process of FIG. 8 and sequentially loads data into the first RAM 23 (step S1).
Reset processing (step S2), start processing of each device in the receiver RE (step S3), and then proceed to step S4. In step S4, data indicating the ON state of the first collective non-interlocking switch SW1 is written into a predetermined memory area A1 of the first RAM 23, and the data in the first batch non-interlocking switch SW1 is written into a predetermined memory area of the dual port RAM 38. Then, a process of writing operation data for turning on the LED is performed, and the process proceeds to step S5. When the above operation data is written in the dual port RAM 38, the operation display CPU 31 reads the operation data,
The LED in the first batch non-interlocking switch SW1 is turned on.

In step S5, the individual non-interlocking switches 501 are stored in predetermined memory areas A2, A3,.
Processing for writing the data indicating the switch-on state of .about.516 and writing the operation data for causing the display mode of the display windows of the individual non-interlocking switches 501 to 516 to flicker (red flicker) in a predetermined memory area of the dual port RAM 38. do. Then, the setting process ends, and the process proceeds to a normal main control process. When the operation data is written in the dual port RAM 38, the operation display CPU 31 reads the operation data and transmits the operation data to the LCD CPU 41.
Outputs a predetermined signal to the LCD display output circuit 45 based on the operation data, and flicker (red flicker) is displayed on the display windows of the individual non-interlocking switches 501 to 516 of the liquid crystal display 52A.

On the other hand, when the power of the system is once turned off and then turned on again, the process branches to the setting process of FIG.
The reset process of 21 is performed, and the process proceeds to step S12. In step S12, it is determined whether the setting of the DIP switch 24 is “0” or “1”. If “0”, the process proceeds to step S13. If “1”, the process proceeds to step S14.
Move to As a result, when the process proceeds to step S13,
It is determined whether the second batch non-interlocking switch SW2 is on or off. If it is on, the process proceeds to step S15, and if it is off, the process proceeds to step S16.

As a result of the branch processing in steps S12 and S13, when the processing shifts to step S14, the storage areas A1, A2 # of the first RAM 23 (the first collective non-interlocking switch SW1 and the individual non-interlocking switches 501 to 5)
16 setting states are stored. ), The data indicating the ON state is written to all of the storage areas A1, A2 #, and at the same time, the dual port RAM 38
Of the first collective non-interlocking switch SW1
Data to turn on ED and individual non-interlocking switch 501
A process of writing operation data that causes the display mode of the display windows 516 to flicker (red flicker) is performed. That is, by the processing of step S14, the first collective non-interlocking switch SW1 and the individual non-interlocking switches 501 to 5
It is started in a state where all 16 setting values are ON (non-interlocked state).

When the process proceeds to step S15, the data in the storage area A1 of the first RAM 23 (which stores the setting state of the first batch non-interlocking switch SW1) is cleared, and the data indicating the ON state is cleared. In addition to writing, storage areas A2, A3 # (individual non-interlock switch 501)
516 are stored. ) Is written as it is, and operation data corresponding to the data in the storage areas A1, A2,... Is written to a predetermined area of the dual port RAM 38. In other words, by the processing of step S15, the setting state of the first collective non-interlocking switch SW1 is in the ON state, and the setting values of the individual non-interlocking switches 501 to 516 are activated with the settings when the power is turned off.

When the process proceeds to step S16, all the data in the storage areas A1, A2,... Are left as they are, and the operation data corresponding to the data in the storage areas A1, A2,. Do the processing. That is, by the processing in step S16, the set state values of the first collective non-interlocking switch SW1 and the individual non-interlocking switches 501 to 516 are activated with the settings when the power is turned off. Then, in step S14,
After any of the processes in S15 and S16 is performed, the setting process ends, and the process proceeds to a normal main control process.
The normal fire monitoring process described above is performed.

As described above, according to the disaster prevention system 1 of this embodiment, by setting the first batch non-interlocking switch SW1, all the smoke prevention devices ER1, ER2 # are collectively linked to the fire signal. Since it can be set to a state in which no fire is caused, when starting up the system or adjusting the system, etc., the smoke detectors ER1 and ER2 due to a malfunction of the fire detectors S1 and S2 # (a fire signal is output even though it is not a fire).制 御 can be prevented beforehand. Further, by setting the individual non-interlocking switches 501 to 516, the smoke control devices ER1, ER
Since 2 ‥ can be set so as not to be interlocked with a fire signal individually for each area or type, for example, when adjusting the system for each area, or for a specific type of smoke prevention equipment ER1, ER2
This is convenient when adjusting ‥.

Further, arbitrary smoke elimination devices ER1, ER2 ‥
Can be set from both the collective non-interlocking switch SW1 and the individual non-interlocking switches 501 to 516,
Further, since a double non-interlocking state can be set by both of these settings, the first collective non-interlocking switch SW1 can be used with the specific smoke prevention devices ER1, ER2 # individually set to the non-interlocking state. By turning the setting on / off,
For example, when adjusting the system, a specific smoke control device ER1,
ER2 ‥ is always in the non-interlocking state, and other smoke suppression equipment ER
1, ER2} can easily perform a switching operation such as setting a non-interlocking state after a while.

When the setting of the non-interlocking state by the first collective non-interlocking switch SW1 is canceled by the blinking display of the LED in the first collective non-interlocking switch SW1, the setting of the individual non-interlocking state is still performed. Since it is possible to identify whether or not there is a non-interlocking state by the individual non-interlocking switches 501 to 516, the first batch non-interlocking switch SW1
By simply canceling the setting, the misunderstanding that all the non-interlocked states have been canceled can be prevented beforehand.

The individual non-interlocking switches 501 to 516
, The individual non-interlocking switches 501-
When the setting of 516 is switched to interlocking, it can be identified whether the setting is switched from the double setting to the single setting or the setting is released from the single setting. Further, when the setting of the individual non-interlocking switches 501 to 516 is switched to the non-interlocking state, it is possible to identify whether the interlocking state is changed to the single non-interlocking state or the single setting is changed to the double setting. I can do it. That is, when the setting of the individual non-interlocked state is switched, it can be determined whether or not the setting is actually effective. Therefore, for example, the individual non-interlocking switches 501 to
When changing the setting pattern by 516, the setting pattern is changed once with the collective non-interlocking state by the first collective non-interlocking switch SW1 interposed between the changes.
In the case where the setting of the first collective non-interlocking switch SW1 is canceled to enable the changed setting pattern to be uniformly enabled, the intervention of the first collective non-interlocking switch SW1 is surely recognized. In this state, the user can change the setting.

When the system is started, the first
Since the setting of the collective non-interlocking switch SW1 and the setting of the individual non-interlocking switches 501 to 516 are both started in the non-interlocking state, the malfunction of the fire detector when the system starts up (a fire signal , Etc.) can be prevented beforehand.

When the power of the system is turned on again,
The setting of the first collective non-interlocking switch SW1 and the setting of the individual non-interlocking switches 501 to 516 can be set so as to be restored to the setting state when the power is turned off. This is convenient because it does not need to be restarted. Also, when the power is turned on again, the setting of the non-interlocked state does not change to the setting of interlocking. It is possible to prevent the control of the smoke elimination devices ER1 and ER2 # by a fire signal or the like beforehand. When the power is turned on again, the setting of the first batch non-interlocking switch SW1 and
Since the settings of the individual non-interlocking switches 501 to 516 can be set so that they are all turned on (non-interlocking state) and activated, by doing so, it is possible to prevent the fire detector from malfunctioning when the power is turned on again. Smoke equipment ER1, ER
2) control can be reliably prevented. When the power is turned on again, only the setting of the first collective non-interlocking switch SW1 can be set to the ON state, and the settings of the individual non-interlocking switches 501 to 516 can be restored to the setting state when the power is turned off. Therefore, by doing so, when the power is turned on again, the smoke detectors ER1,
The control of ER2 # can be reliably prevented, and the individual non-interlocking switches 501 to 516 for which detailed settings are made need not be set again from the beginning, which is convenient. And
Since these three types of activation methods can be selected by setting the second collective non-interlocking switch SW2 and the DIP switch 24, it is possible to cope with various restart states.

Note that the present invention is not limited to the disaster prevention system 1 of this embodiment, and can be appropriately changed without departing from the spirit of the invention. For example, as examples of smoke prevention equipment, fire prevention dampers, fire prevention shutters, fire doors, and the like have been given as examples. However, the invention is not limited to these, and control is performed in conjunction with a fire signal from a fire detector using equipment that prevents the spread of fire or smoke. If it is a device, everything is included. In addition, the setting unit of the predetermined smoke-prevention device which can be individually non-interlocked by the individual non-interlocking setting means is not limited to the installation area and the type of the smoke-prevention device, but is set in any category and condition. Units may be used. Further, the display mode of the display unit or the display unit, which indicates the setting state of the batch non-interlocking setting unit or the individual non-interlocking setting unit, is not limited to the contents of Table 1 described above. May be displayed, and various modes are possible.

[0089]

According to the first aspect of the present invention, all of the smoke control devices can be collectively set so as not to be linked to the fire signal, so that when starting the system or adjusting the system, the fire is prevented. It is possible to prevent the control of the smoke elimination device due to a malfunction of the detector (a fire signal is output even though it is not a fire). Furthermore, since it is possible to set the predetermined smoke prevention devices individually so as not to be linked with the fire signal, it is convenient when individually adjusting the predetermined smoke prevention devices. For example, according to the second aspect of the present invention, it is convenient when adjusting the system for each area, and according to the third aspect of the present invention, a specific type of smoke prevention equipment is adjusted. It is convenient at times.

According to the fourth aspect of the present invention, the setting for disabling an arbitrary smoke prevention device can be performed by both the collective non-interlocking setting means and the individual non-interlocking setting means. , A double non-interlocked state can be set. Therefore, by turning on / off the setting by the collective non-interlocking setting means in a state where the specific smoke prevention equipment is individually set to the non-interlocking state, for example, when the system is adjusted, the specific smoke prevention equipment is always set. In the non-interlocked state, the other smoke prevention equipment can easily perform a switching operation such that the non-interlocked state is released at a later time.

According to the fifth aspect of the present invention, when the setting of the non-interlocking state by the collective non-interlocking setting means is canceled, it can be determined whether or not there is still an individual non-interlocking state setting.
Therefore, although there is a setting of the non-interlocking state by the individual non-interlocking setting means, it is possible to prevent a misunderstanding that all the non-interlocking states are released only by canceling the setting of the collective non-interlocking setting means.

According to the sixth aspect of the present invention, when the setting of the individual non-interlocking setting means is switched to interlocking, it is determined whether the setting is switched from the double setting to the single setting or the setting is released from the single setting. You can do it. Also, when switching the setting of the individual non-interlocking setting means to the non-interlocking state,
It is possible to identify whether the setting is changed from the linked state to the single non-linked state, or from the single setting to the double setting. That is, when switching the setting of the individual non-linked state,
Whether or not the setting is actually effective can be identified. Therefore, for example, when changing the setting pattern by the individual non-interlocking setting means, the setting pattern is changed once by interposing the collective non-interlocking state by the collective non-interlocking setting means during the change, and When making a change such as enabling the changed setting pattern uniformly by canceling the setting of the setting means, perform the setting change operation in a state in which such intervention of the batch non-interlocking setting means is securely recognized. I can do it.

According to the seventh aspect of the present invention, the plurality of display windows provided in the display means ensure that the entire set unit can be recognized and operated, and that the set unit which can be set individually can be set. The number can be increased.

According to the eighth aspect of the present invention, it is possible to prevent a malfunction of the fire detector (a fire signal is output even though it is not a fire, etc.) at the time of starting the system, thereby preventing the control of the smoke control device. .

According to the ninth aspect of the present invention, even if the power of the collective non- interlocking setting means or the individual non-interlocking setting means is turned off at the time of system adjustment or the like, the setting state is restored when the power is turned on again. Becomes possible.

According to the tenth aspect of the present invention, even when the power of the system is once turned off and then turned on again, for example, at the time of system adjustment, the setting of interlocking / non-interlocking is the same as before the power was turned off. This is convenient because it is not necessary to reset the settings from the beginning. In addition, when the power is turned on again, the setting of the non-interlocked state does not change to the setting of the interlocked state. Therefore, when the power is turned on again, the fire detector malfunctions (fire signal is output even though it is not a fire). It is possible to prevent the control of smoke elimination equipment.

According to the eleventh aspect of the present invention, the setting of the first control state setting means is made to be the latter, whereby the tenth aspect of the present invention is provided.
The operation and effect of the invention described in the claims are exhibited, and by setting the first control state setting means to the former, a malfunction of the fire detector (a fire signal is output even though it is not a fire) when the power is turned on again Control of the smoke emission control device can be reliably prevented. Therefore, by changing the setting of the first control state setting means, the state of the system when the power is turned on again becomes
It is possible to cope with a case where there is not much difference from when the power is turned off and a case where there is a possibility that the power is greatly changed from when the power is turned off.

According to the twelfth aspect, the first aspect
In addition to the operation and effect of the invention described in 1 above, by setting by the second control state setting means, the setting of the collective non-interlocking setting means becomes a collective non-interlocking state when the power is turned on again.
The control of the smoke prevention device due to the malfunction of the fire detector can be reliably prevented, and the individual non-interlocking setting means, which can have various setting states, does not need to be reset from the beginning, which is convenient.

[Brief description of the drawings]

FIG. 1 is a configuration diagram showing an entire disaster prevention system according to an embodiment of the present invention.

FIG. 2 is a plan view showing an operation panel of the receiver in FIG.

FIG. 3 is a block diagram showing a configuration of the receiver.

FIG. 4 is a display image diagram of an individual non-interlocking switch displayed on the LCD of FIG. 3;

FIG. 5 is a memory configuration diagram of a first RAM of the receiver, showing an example of a data storage portion storing setting states of a first collective non-interlocking switch SW1 and an individual non-interlocking switch.

FIG. 6 is a memory configuration diagram of a first ROM of the receiver, showing an example of a data storage portion storing various information of a fire detector and a smoke prevention device.

FIG. 7 is a first R of a receiver showing another example of the data storage portion storing various information of the fire detector and the smoke prevention device.
FIG. 3 is a memory configuration diagram of the OM.

FIG. 8 is a part of a flowchart of a main control process performed by the main control circuit of the receiver when starting up the system.

FIG. 9 is a part of a flowchart of main control processing at the time of system restart performed by the main control circuit of the receiver.

[Explanation of symbols]

Reference Signs List 1 disaster prevention system RE receiver 20 main control circuit 23 first RAM (constituting setting state storage means) 24 dip switch (constituting first and second control state setting means) 30 operation display Control circuit 40 Liquid crystal control circuit 50 Operation panel 52 Liquid crystal display unit 60 Main operation display unit SW1 First batch non-interlocking switch (constituting batch non-interlocking setting means) SW2 Second batch non-interlocking switch (No. First and second control state setting means.) 501 to 516 individual non-interlocking switches (constituting individual non-interlocking setting means) S1, S2１ ， Fire detectors ER1, ER2 ‥ Smoke elimination machine

Continuation of the front page (56) References JP-A-4-20993 (JP, A) JP-A-7-121781 (JP, A) JP-A-1-205300 (JP, A) (58) Fields investigated (Int) .Cl. ⁷ , DB name) G08B 17/00 G08B 23/00-31/00 A62B 13/00

Claims (12)

(57) [Claims] A plurality of fire detectors for detecting a fire and outputting a fire signal; a plurality of smoke prevention devices for preventing the spread of fire and smoke; and receiving a signal from the fire detector and and a transmission capable receiver signals to Bohai smoke device side, a disaster prevention system for controlling operation of the Bohai smoke device is predetermined in conjunction with the fire signal of the fire detector, the operation input, In the disaster prevention system including the batch non-interlocking setting means for setting the non-interlocking state of all of the smoke prevention devices collectively in the non-interlocking state, the operation of the smoke prevention devices is preliminarily controlled to operate in conjunction with the operation input. Determined
And the operation control of the Bohai smoke devices, as well as a configurable non-interlocked state separately for a given Bohai smoke devices, this
A disaster prevention system comprising an individual non-interlocking setting unit capable of canceling a setting. 2. The plurality of smoke control devices are provided in a plurality of areas, and the individual non-interlocking setting means controls the operation of the smoke control devices based on the fire signal in an area where the smoke control devices are provided. The disaster prevention system according to claim 1, wherein the system can be set to a non-interlocking state every time. 3. The smoke control device has a plurality of types, and the individual non-interlocking setting means can set an operation control of the smoke control device based on the fire signal to a non-interlocking state for each type of the smoke control device. The disaster prevention system according to claim 1 or 2, wherein 4. The operation control of an arbitrary smoke prevention device among the operation control of the smoke prevention device based on the fire signal is performed in a non-interlocked state by both the collective non-interlock setting unit and the individual non-interlock setting unit. When the setting of the non-interlocking state is performed in one of the collective non-interlocking setting means and the individual non-interlocking setting means, the operation control is not performed for the arbitrary smoke prevention device. The disaster prevention system according to any one of claims 1 to 3, wherein 5. A display unit for displaying a setting state by said collective non-interlocking setting means, wherein said display unit displays said individual non-interlocking state when said non-interlocking state is not set by said collective non-interlocking setting means. The disaster prevention system according to any one of claims 1 to 4, wherein a display capable of identifying whether or not there is a setting of a non-interlocking state by the interlocking setting means is performed. 6. A display device for displaying a setting state of said individual non-interlocking setting means, wherein said display means performs setting of a double non-interlocking state by said collective non-interlocking setting means and individual non-interlocking setting means. 6. A display capable of identifying whether the setting is performed, or whether the non-interlocking state is set by one of the collective non-interlocking setting means and the individual non-interlocking setting means. The disaster prevention system according to any one of the above. 7. The individual non-interlocking setting means can set the operation control of the smoke prevention equipment based on the fire signal to a non-interlocking state for each predetermined setting unit. A plurality of display windows corresponding to each of the setting units are provided, and a setting state of the predetermined setting unit corresponding to each display window is displayed on each of the display windows. 7. A touch operation input means capable of performing an operation input by a touch operation and setting a non-interlocking state of the predetermined setting unit corresponding to each display window portion is provided. Disaster prevention system. 8. When the system is started, the setting of the collective non- interlocking setting means is set to the non-interlocking state, and the setting of the individual non-interlocking setting means is set to the non-interlocking state for all settable smoke prevention devices. The disaster prevention system according to any one of claims 1 to 7, wherein: 9. The apparatus according to claim 1, further comprising a setting state storage means for storing respective setting states of said collective non- interlocking setting means and individual non-interlocking setting means. Disaster prevention system. 10. The system according to claim 9, wherein when the system is restarted, the settings of the batch non- interlocking setting means and the individual non-interlocking setting means are set to the setting states stored in the setting state storage means. The described disaster prevention system. 11. When the system is restarted, the settings of the collective non-interlocking setting means and the individual non-interlocking setting means are all set to the non-interlocking state, or set to the setting state stored in the setting state storage means. 10. The disaster prevention system according to claim 9, further comprising a first control state setting unit that can selectively set the control state. 12. When the system is restarted, the setting of the collective non-interlocking setting means is set to the non-interlocking state, and the setting of the individual non-interlocking setting means is set to the setting state stored in the setting state storage means. The disaster prevention system according to claim 11, further comprising a second control state setting unit capable of performing the control.