CN211854089U

CN211854089U - Single-needle ignition fire detection device

Info

Publication number: CN211854089U
Application number: CN201922492337.XU
Authority: CN
Inventors: 屈小娟; 耿凯平; 李飞龙; 汪福平
Original assignee: Shenzhen Zhigu Tianchef Technology Co ltd
Current assignee: Shenzhen Zhigu Tianchef Technology Co ltd
Priority date: 2019-12-30
Filing date: 2019-12-30
Publication date: 2020-11-03
Anticipated expiration: 2029-12-30

Abstract

The utility model discloses a fire device is examined in single needle ignition, wherein, this fire device is examined in single needle ignition includes: the ignition fire detection needle is connected with the central processing unit through an ignition circuit and a fire detection circuit; the central processing unit controls the ignition fire detection needle to discharge and ignite based on the ignition circuit and controls the ignition fire detection needle to perform flame detection based on the ignition circuit respectively in different time periods. Realized, examine the fire needle with an ignition and utilize the multiplexing principle of timesharing based on central processing unit, examine the fire needle discharge ignition based on this ignition of ignition circuit control at different periods, and examine the fire needle and carry out flame detection based on examining this ignition of ignition circuit control, two discharge needles that are used for the ignition respectively with being used for examining the fire with the tradition unite two into one, the overall structure of ignition fire detection device has been simplified, the installation production of both being convenient for, manufacturing cost has also been reduced, cooking robot's rapid development and popularization and application demand have been satisfied.

Description

Single-needle ignition fire detection device

Technical Field

The utility model relates to a gas ignition examines fiery technical field, in particular to fire device is examined in single needle ignition.

Background

With the rapid development and popularization and application of cooking robots, the market demand of the cooking robots has become stronger and stronger. However, the ignition and fire detection device applied by the existing gas cooking robot respectively uses two sets of independent ignition and fire detection structures, namely, one discharge needle is independently used by an ignition circuit for ignition operation, and the other discharge needle is independently used by a fire detection circuit for flame detection operation, so that the whole structure of the ignition and fire detection device is complex, the installation and production of the device are not convenient, and the manufacturing cost of the device is relatively high.

SUMMERY OF THE UTILITY MODEL

The utility model mainly aims at providing a fire device is examined in single needle ignition aims at simplifying the ignition and examines fire device structure, reduces device manufacturing cost.

In order to achieve the above object, the utility model provides a fire device is examined in single needle ignition, the fire device is examined in single needle ignition includes: the ignition circuit and the ignition detecting circuit are connected in parallel between the ignition detecting needle and the central processing unit;

the central processing unit activates the ignition circuit and the fire detection circuit in a time-sharing manner, so that the time-sharing ignition and fire detection of the ignition and fire detection needle are realized.

In one embodiment, the single-needle ignition fire detection apparatus further includes: the power supply is respectively connected with the ignition circuit and the ignition detecting circuit;

the power supply is used for providing alternating current or direct current for the ignition circuit and the ignition detecting circuit.

In one embodiment, the ignition fire detection needle includes: an ignition module;

the ignition fire detection needle is connected with the ignition circuit based on the ignition module, and discharges and ignites after the ignition circuit boosts the alternating current provided by the power supply.

In one embodiment, the ignition fire detection needle further comprises: a fire detection module;

the ignition fire detection needle is connected with the fire detection circuit based on the fire detection module, and when the fire detection circuit acquires an alternating current signal from alternating current provided by the power supply, the flame detection is carried out by combining the unidirectional conductivity of flame.

In one embodiment, the single-needle ignition fire detection apparatus further includes: the timer is connected with the central processing unit;

when the central processing unit receives an ignition signal, the ignition circuit is activated to control the ignition fire detection needle to discharge and ignite;

and after the timer times a first time, the central processing unit activates the flame detection circuit to control the ignition flame detection needle to perform flame detection.

In an embodiment, if the central processing unit controls the ignition fire detection needle to perform flame detection to detect flame after the timer counts a first time period, the ignition fire detection needle is controlled to perform flame detection continuously after the timer counts a second time period.

In one embodiment, the single-needle ignition fire detection apparatus further includes: the counter is connected with the central processing unit;

if the central processing unit controls the ignition fire detection needle to perform flame detection and does not detect flame after the timer counts the first time, the ignition fire detection needle is controlled to perform discharge ignition again until the counter records that the number of times of discharge ignition of the ignition fire detection needle controlled by the central processing unit reaches the preset number of times.

In one embodiment, the single-needle ignition fire detection apparatus further includes: the alarm module is connected with the central processing unit;

and the central processing unit controls the alarm module to output an alarm signal after the counter records that the number of times of discharge and ignition of the ignition fire detection needle controlled by the central processing unit reaches a preset number of times.

In an embodiment, if the central processing unit controls the ignition fire detection needle to continuously perform flame detection and does not detect flame after the timer counts the second time period, the central processing unit controls the alarm module to output an alarm signal.

In one embodiment, the central processing unit activates the ignition circuit to control the ignition fire detection needle to continuously perform flame detection before activating the ignition circuit to control the ignition fire detection needle to discharge and ignite, and controls the alarm module to output a false flame signal when a flame is detected.

The technical scheme of the utility model is that an ignition device is provided, an ignition circuit, a fire detection circuit, an ignition fire detection needle and a central processing unit are arranged in the ignition device, and the ignition circuit and the fire detection circuit are connected in parallel between the ignition fire detection needle and the central processing unit; the central processing unit activates the ignition circuit and the fire detection circuit in a time-sharing manner, so that the time-sharing ignition and fire detection of the ignition and fire detection needle are realized. Realized, examine the fire needle with an ignition and utilize the multiplexing principle of timesharing based on central processing unit, this ignition of ignition is examined the fire needle and is discharged and ignite at different periods activation ignition circuit control, examine the fire needle with the activation and examine this ignition of fire circuit control and carry out flame detection, two discharge needles that are used for the ignition respectively with being used for examining the fire with the tradition unite two into one, the overall structure of ignition fire detection device has been simplified, the installation production of both being convenient for, manufacturing cost has also been reduced, cooking robot's rapid development and popularization and application demand have been satisfied.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

FIG. 1 is a schematic structural view of an embodiment of the single-needle ignition fire detection device of the present invention;

FIG. 2 is a schematic structural view of an ignition and fire detection needle in an embodiment of the single-needle ignition and fire detection device of the present invention;

fig. 3 is a schematic structural view of another embodiment of the single-needle ignition fire detection device of the present invention.

The reference numbers illustrate:

reference numerals	Name (R)	Reference numerals	Name (R)
				10	Ignition fire detection needle	20	Central processing unit
30	Ignition circuit	40	Fire detection circuit
				50	Power supply	60	Time-meter
70	Counter with a memory	80	Alarm module
				11	Ignition module	12	Fire detection module

The objects, features and advantages of the present invention will be further described with reference to the accompanying drawings.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

It should be noted that if the embodiments of the present invention are described with reference to "first", "second", etc., the description of "first", "second", etc. is only for descriptive purposes and is not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature.

The utility model provides a fire device is examined in single needle ignition.

In an embodiment of the present invention, as shown in fig. 1, the structure of the single-needle ignition fire detection device includes: the ignition and fire detection device comprises an ignition and fire detection needle 10, a central processing unit 20, an ignition circuit 30 and a fire detection circuit 40, wherein the ignition circuit 30 and the fire detection circuit 40 are connected in parallel between the ignition and fire detection needle 10 and the central processing unit 20;

the central processing unit 20 activates the ignition circuit 30 and the ignition detecting circuit 40 in a time-sharing manner, so that time-sharing ignition and ignition detection of the ignition detecting needle 10 are realized.

In the scheme, the central processor 20 respectively activates the ignition circuit 30 to control the ignition fire detection needle 10 to discharge and ignite at different time intervals, and activates the fire detection circuit 40 to control the ignition fire detection needle 10 to perform flame detection.

In the present disclosure, the central processing unit 20 may be a single chip, a DSP (digital signal processing), and the like, and it should be understood that the present disclosure does not limit the specific type, parameters, and the like of the central processing unit 20.

In one embodiment, referring to the structure of the single needle ignition fire detection apparatus as shown in fig. 1, the single needle ignition fire detection apparatus further includes: a power supply 50 connected to the ignition circuit 30 and the ignition detecting circuit 40, respectively; the power supply 50 is used to supply ac power or dc power to the ignition circuit 30 and the ignition detecting circuit 40.

Specifically, the power supply circuit 50 may be any internal or external power source that provides 220V ac power.

In one embodiment, referring to the structure of the ignition flame-detecting needle 10 as shown in fig. 2, the ignition flame-detecting needle 10 includes: an ignition module 11.

In this embodiment, the ignition fire detection needle 10 is connected to the ignition circuit 30 based on the ignition module 11, the circuit 30 to be ignited obtains 220V alternating current from the power supply 50, and boosts the 220V alternating current to a high voltage of ten thousand volts above 10kv by using a transformer principle, and then the ignition fire detection needle 10 discharges electricity between the shells of the single-needle ignition fire detection device, so as to ignite the gas to realize ignition.

Further, in another embodiment, the circuit to be ignited 30 may further obtain 220V direct current from the power supply 50, then convert the direct current into 220V direct current and alternating current, then boost the 220V alternating current by using a transformer principle to reach a high voltage of ten thousand volts above 10kv, and then discharge between the shells of the single-needle ignition and fire detection device by the ignition and fire detection needle 10, thereby igniting the gas to realize ignition.

In one embodiment, referring to the structure of the ignition flame-detecting needle 10 as shown in fig. 2, the ignition flame-detecting needle 10 includes: and a fire detection module 12.

In this embodiment, the ignition fire detection needle 10 is connected with the fire detection circuit 40 based on the fire detection module 12, the fire detection circuit 40 to be detected obtains an alternating current signal from alternating current provided by the power supply 50, and then the flame is unidirectional in conductivity, that is, when there is flame, the alternating current signal is rectified into a direct current signal by the flame to detect whether there is flame.

In an embodiment, referring to the structure of the single-needle ignition fire detection device as shown in fig. 3, the utility model provides a single-needle ignition fire detection device, further includes: a timer 60 connected to the central processor 20.

In the present embodiment, upon receiving an ignition instruction triggered by the user based on the cooking robot, the ignition circuit 30 is activated to call the ignition module 11 for controlling the ignition fire detection needle 10 to discharge and ignite, since a leakage current signal flows from the secondary side of the ignition circuit 30 to the ground when a spark is generated in the ignition stage, the current signal in the ignition circuit 40 may be affected, therefore, in the stage that the central processing unit 20 controls the ignition fire detection needle 10 to discharge and ignite, the fire detection circuit 40 is not activated at the same time to control the ignition fire detection needle 10 to perform flame detection, after the ignition control fire detection needle 10 is waited for discharge ignition, the timer 60 connected with the central processor 20 activates the fire detection circuit 40 to control the fire detection module 12 of the ignition fire detection needle 10 to perform flame detection so as to detect whether a flame signal exists or not after a first time period.

In the present embodiment, the first time period recorded by the timer 60 may be set autonomously based on the ignition performance of the ignition detection 10 and the ignition module 11 for discharging ignition, and may be set to any one time period of 1 to 3 seconds, for example.

In an embodiment, referring to the structure of the single-needle ignition fire detection device as shown in fig. 3, the utility model provides a single-needle ignition fire detection device, further includes: a counter 70 connected to the central processor 20.

The central processor 20 activates the ignition circuit 30 to call the ignition module 11 of the ignition control fire detection needle 10 to perform discharge ignition according to an ignition instruction triggered by a received user, activates the ignition circuit 40 to call the ignition module 12 of the ignition control fire detection needle 10 to perform flame detection to detect whether a flame signal exists or not after waiting for the timer 60 to time for 1 second, activates the ignition circuit 30 again to call the ignition module 11 of the ignition control fire detection needle 10 to perform discharge ignition by the central processor 20 if the flame detection module 12 does not detect flame at this time, and repeats the process until the counter 70 connected with the central processor 20 records that the number of times that the central processor 20 activates the ignition circuit 30 to call the ignition module 11 of the ignition control fire detection needle 10 to perform discharge ignition reaches a preset number of times, and then terminates.

In the present embodiment, the counter 70 counts the number of pulses based on the counting operation to realize the counting function, and specifically, the counter 70 may be composed of a basic counting unit and a plurality of control gates, and the counting unit is composed of a series of various flip-flops having a function of storing information, such as an RS flip-flop, a T flip-flop, a D flip-flop, and a JK flip-flop. The preset number of times may be set independently based on a user or a device manufacturer, for example, 3 times, and in this embodiment, when the number of times that the central processor 20 controls the ignition fire detection needle 10 to perform discharge ignition based on the ignition circuit 30 does not reach the preset number of times (for example, 3 times), but when the flame signal is detected by controlling the ignition fire detection needle 10 to perform flame detection based on the ignition circuit 40, the central processor 20 will also terminate continuing to perform discharge ignition based on the ignition circuit 30 controlling the ignition fire detection needle 10.

In an embodiment, referring to the structure of the single-needle ignition fire detection device as shown in fig. 3, the utility model provides a single-needle ignition fire detection device, further includes: an alarm module 80 connected to the central processor 20.

When the counter 70 connected to the central processor 20 records that the number of times that the central processor 20 activates the ignition circuit 30 to call the ignition module 11 controlling the ignition fire detection needle 10 to perform discharge ignition reaches a preset number of times (for example, 3 times), but when the fire detection module 12 controlling the ignition fire detection needle 10 is called based on the fire detection circuit 40 to perform flame detection but still does not detect a flame signal, the central processor 20 will terminate continuing to control the ignition fire detection needle 10 to perform discharge ignition based on the ignition circuit 30, and simultaneously close the gas valve, and control the alarm module 80 connected to the central processor 20 to output an alarm signal for the user to check.

In this embodiment, the alarm module 80 connected to the central processing unit 20 may be specifically a buzzer, an indicator light capable of outputting lights with different colors, or a wireless module that sends an alarm signal to a terminal device connected to the module, such as a mobile phone, based on a wireless transmission function.

In one embodiment, after the central processing unit 20 activates the ignition circuit 30 to call the ignition module 11 controlling the ignition fire detection needle 10 to perform discharge ignition, activates the fire detection circuit 40 to call the fire detection module 12 controlling the ignition fire detection needle 10 to perform flame detection after waiting for the timer 60 to count for 1 second time, and after detecting the flame signal, the central processing unit 20 activates the fire detection circuit 40 to control the fire detection module 12 controlling the ignition fire detection needle 10 to perform flame detection every second time counted by the timer 60.

In this embodiment, the second time period timed by the timer 60 may be set autonomously based on the performance of the ignition fire detection pin 10 for flame detection by the ignition fire detection pin 12, for example, set to any time period between 10 and 30 milliseconds, and the time period is used for activating the ignition module 12 of the ignition fire detection pin 10 by the central processing unit 20 to detect the presence or absence of a flame signal after the timer 60 detects that the central processing unit 20 activates the ignition circuit 30 to invoke the ignition module 11 of the ignition fire detection pin 10 to perform successful discharge ignition, and after the interval and the continuous timing, the central processing unit 20 activates the ignition circuit 40 to control the ignition fire detection pin 10 to detect the presence or absence of a.

In the present embodiment, in the process of continuously performing flame signal detection by activating the flame detecting circuit 40 to call the flame detecting module 12 for controlling the ignition flame detecting needle 10 every time (for example, 20 milliseconds) by the cpu 20 waiting for the timer 60 to count time, an algorithm of multiple hand voting is adopted, that is, flame signals are continuously detected at a certain time interval, the flame signal at a certain time point is based on the data of the current sampling point and N (N is an odd number) time points before the current point (the total is the detection results of the presence or absence of the odd number of detected flame signals), and the presence or absence result of most of the consistent flame signals is taken as the detection result of currently performing flame detection, for example, 5 time points, and if the detection result of not less than 3 times is the presence of flame, the final detection result is the presence of flame. It should be understood that, in the present application, in order to increase the detection reliability, the value of N may be adjusted, and the present application does not limit the value.

In one embodiment, in the process that the central processor 20 waits for the timer 60 to count (for example, 20 milliseconds) every time, the fire detection circuit 40 is activated to call the fire detection module 12 for controlling the ignition fire detection needle 10 to continuously perform flame signal detection, and after the fire detection module 12 detects and determines that no flame is currently detected, it is immediately determined that the current cooking robot may cause fire extinguishment based on objective conditions, the central processor 20 immediately closes the gas valve to stop continuing gas supply, and controls the alarm module 80 connected with the central processor 20 to output an alarm signal for the user to know.

In this embodiment, if the central processing unit 20 controls to close the gas valve to stop continuing supplying gas based on a fire extinguishing instruction triggered by the user, and activates the fire detection circuit 40 again to call the fire detection module 12 for controlling the ignition fire detection needle 10 to continuously perform flame detection, and no flame is detected, the central processing unit 20 will not output an alarm signal.

In one embodiment, before the central processor 20 activates the ignition circuit 30 to invoke the ignition module controlling the ignition fire detection needle 10 to perform discharge ignition according to the received user-triggered ignition instruction, the central processor 20 still waits for the timer 60 to count (for example, 20 ms) each time, activates the ignition circuit 40 to invoke the ignition module 12 controlling the ignition fire detection needle 10 to continue the process of flame signal detection, and if the flame signal is detected by the ignition module 12 of the ignition fire detection needle 10 during the process, the central processor 20 controls the alarm module 80 connected to the central processor 20 to output a false flame signal, for the user to know and check and repair, ensure that after the central processor 20 activates the ignition circuit 30 to control the ignition module 11 of the ignition detection needle 10 to successfully perform discharge ignition, activating the fire detection circuit 40 calls the fire detection module 12 controlling the fire detection needle 10 to continuously perform the accuracy of the flame detection process.

The technical scheme of the utility model is that through providing a single-needle ignition fire detection device, an ignition circuit 30, a fire detection circuit 40, an ignition fire detection needle 10 and a central processing unit 20 are arranged in the single-needle ignition fire detection device, and the ignition circuit 30 and the fire detection circuit 40 are connected in parallel between the ignition fire detection needle 10 and the central processing unit 20; the central processing unit 20 activates the ignition circuit 30 and the ignition detecting circuit 40 in a time-sharing manner, so that time-sharing ignition and ignition detection of the ignition detecting needle 10 are realized.

The utility model discloses technical scheme has realized, examine fire needle 10 based on central processing unit 20 utilizes the multiplexing principle of timesharing with an ignition, activate ignition circuit 30 control this ignition of different periods and examine fire needle 10 and discharge the ignition, examine with the activation that this ignition of thermal circuit 40 control is examined fire needle 10 and is carried out flame detection, two discharge needles that are used for the ignition respectively with being used for examining the fire with the tradition unite two into one, the overall structure of ignition fire detection device has been simplified, the installation and production of both being convenient for, manufacturing cost has also been reduced, cooking robot's rapid development and popularization and application demand have been satisfied.

It should be noted that the above mentioned is only the preferred embodiment of the present invention, and not to limit the scope of the present invention, and all the equivalent structural changes made by the contents of the specification and the drawings or the direct/indirect application in other related technical fields are included in the protection scope of the present invention.

Claims

1. A single needle ignition fire detection device, characterized in that, single needle ignition fire detection device includes: the ignition circuit and the ignition detecting circuit are connected in parallel between the ignition detecting needle and the central processing unit;

2. The single-needle ignition fire detection apparatus as recited in claim 1, further comprising: the power supply is respectively connected with the ignition circuit and the ignition detecting circuit;

the power supply is used for supplying alternating current or direct current to the ignition circuit and the ignition detecting circuit.

3. The single-needle ignition fire detection device of claim 2, wherein the ignition fire detection needle comprises: an ignition module;

4. The single-needle ignition fire detection device of claim 2, wherein said ignition fire detection needle further comprises: a fire detection module;

5. The single-needle ignition fire detection apparatus as recited in claim 1, further comprising: the timer is connected with the central processing unit;

6. The single-needle ignition fire detection device according to claim 5, wherein if the central processing unit controls the ignition fire detection needle to perform flame detection and detect flame after the timer counts a first time period, the ignition fire detection needle is controlled to perform flame detection continuously after the timer counts a second time period.

7. The single-needle ignition fire detection apparatus as recited in claim 5, further comprising: the counter is connected with the central processing unit;

8. The single-needle ignition fire detection apparatus as recited in claim 7, further comprising: the alarm module is connected with the central processing unit;

9. The single-needle ignition fire detection device according to claim 8, wherein if the central processing unit controls the ignition fire detection needle to continuously perform flame detection after the timer counts every second time period, and no flame is detected, the central processing unit controls the alarm module to output an alarm signal.

10. The single-needle ignition fire detection device of claim 8, wherein said central processor activates said ignition circuit to control said ignition fire detection needle to continue flame detection before activating said ignition circuit to control said ignition fire detection needle to discharge and ignite, and controls said alarm module to output a false flame signal when a flame is detected.