CN217900210U - Novel probe of autonomic temperature sensing and can be according to water temperature automatic control's electric ceramic stove - Google Patents

Abstract

An autonomous temperature-sensing novel probe and an electric ceramic stove capable of being automatically controlled according to water temperature are disclosed, wherein the autonomous temperature-sensing probe consists of a shell, a battery, a circuit module and a temperature sensor, wherein the battery, the circuit module and the temperature sensor are arranged in the shell; the temperature sensor is directly contacted with the inner surface of the shell or embedded into the shell, the temperature sensor, the circuit module and the battery are respectively and sequentially arranged in the shell, and the temperature sensor and the battery are respectively connected with the circuit module, or the battery is arranged between the temperature sensor and the circuit module, and the temperature sensor and the battery are respectively connected with the circuit module; and the radio transmitting module is communicated with the temperature information acquisition module. An independent temperature sensing probe is arranged on a ventilating body channel of a kettle body of the electric ceramic stove or the independent temperature sensing probe is hung at a shell opening, a power switch of a heater of the electric ceramic stove is an electric control switch, and the electric control switch is communicated with a radio transmitting module of the independent temperature sensing probe through a front remote data receiving module. The utility model has the advantages that, independently temperature sensing probe compact structure, small, can the autonomous working in a certain time, and with its application electric ceramic stove can realize that electric ceramic stove produces steam and back automatic control at water, improve electric ceramic stove safety in utilization.

Description

Novel probe of autonomic temperature sensing and can be according to water temperature automatic control's electric ceramic stove

Technical Field

The utility model relates to a temperature sensing probe and utilize electric pottery stove of its temperature sensing probe, in particular to independently temperature sensing probe and utilize electric pottery stove that can realize water boiling automatic control heating of independently temperature sensing probe.

Background

The existing electric ceramic stove is high in temperature, the existing technical means for monitoring whether the electric ceramic stove boils water in lack of time is often not powered off in time after the water is boiled, so that the electric ceramic stove is burnt out or causes fire, electric leakage and the like, application and popularization of the electric ceramic stove are severely restricted, a small temperature sensing probe capable of working independently is arranged on a kettle, the temperature of exhaust gas can be collected in real time, and the electric ceramic stove is powered off in time according to the temperature, so that the operation safety of the electric ceramic stove is protected.

Disclosure of Invention

The utility model provides an autonomic temperature sensing probe and can be according to temperature automatic control's electric pottery stove, autonomic temperature sensing probe compact structure, small, can independent work in a certain time, and with its application electric pottery stove can realize that electric pottery stove produces steam (according to atmospheric pressure difference, the boiling point of water is inequality, produces a large amount of steam and generally is regarded as the characteristic that water was opened) and back automatic control, improvement electric pottery stove safety in utilization.

The technical scheme for realizing the purpose of the utility model is that the autonomous temperature sensing probe consists of a shell, and a battery, a circuit module and a temperature sensor which are arranged in the shell;

the temperature sensor is directly contacted with or embedded into the shell, the temperature sensor, the circuit module and the battery are respectively and sequentially arranged in the shell, and the temperature sensor and the battery are respectively connected with the circuit module, or the battery is arranged between the temperature sensor and the circuit module, and the temperature sensor and the battery are respectively connected with the circuit module;

the circuit module comprises a radio transmitting module and a temperature information acquisition module, the temperature information acquisition module is communicated with the temperature sensor, and the radio transmitting module is communicated with the temperature information acquisition module.

Further, a temperature sensing metal block is arranged on the shell, and the temperature sensor is in contact with the temperature sensing metal block.

Furthermore, the temperature sensing metal block partially extends out of the shell to form an extension part.

Furthermore, the extension part is a plate or an L-shaped or U-shaped.

Furthermore, the shell is provided with a limiting foot.

Furthermore, a ventilation channel is arranged on the shell, and the temperature sensor is in contact with or embedded into the inner wall of the ventilation channel.

Furthermore, a clamping pin is arranged on the shell.

The electric ceramic stove comprises a kettle body and an electric ceramic stove heater for heating the kettle body, wherein an independent temperature sensing probe is arranged on a ventilation body channel of the kettle body or is hung at the opening of the shell, a power switch of the electric ceramic stove heater is an electric control switch, and the electric control switch is communicated with a radio transmitting module of the independent temperature sensing probe through a front remote data receiving module.

Furthermore, a clamping needle is arranged on the autonomous temperature sensing probe, and the clamping nail at least partially enters the channel of the vent body.

Furthermore, the protruding part of the temperature sensing metal plate of the autonomous temperature sensing probe is hung on the edge of the channel of the ventilation body on the shell or partially blocks the flow of gas.

The utility model has the advantages that:

1) The temperature sensor is directly contacted with or embedded into the shell, so that the volume of the automatic temperature sensing probe is reduced to the maximum extent, and meanwhile, the battery or the temperature sensor is arranged to bring a power supply to enable the automatic temperature sensing probe to automatically supply power and independently work within a certain time.

2) The temperature sensor collects the temperature of a shell contacted with the temperature sensor in real time, and the temperature information collecting module of the circuit module transmits the temperature collected by the temperature sensor to the position through the radio transmitting module, so that an independently working temperature collecting and temperature data wireless transmitting system can be formed.

3) Be equipped with spacing foot on the casing, can effectively protect the casing through spacing foot, prevent that the kettle body is direct to contact with the casing, can also make and form a convection current space between the kettle body and the casing, when not having steam, can form the cooling passageway.

3) The temperature sensing metal block partially extends out of the shell to form an extension part, the extension part is arranged, the main body part of the autonomous temperature sensing probe can be separated from the temperature sensing metal block for collecting temperature, and the autonomous temperature sensing probe can be hung on the kettle body through the extension part.

) The shell is provided with a ventilation channel, so that the shell can be directly placed on the kettle body, and the ventilation channel is utilized to exhaust.

Drawings

Fig. 1 is a schematic diagram of an autonomous temperature sensing probe.

FIG. 2 is a schematic cross-sectional view of an autonomous temperature sensing probe.

Fig. 3 is a first preferred schematic diagram of the autonomous temperature sensing probe.

Fig. 4 is a schematic view of a first preferred section of the autonomous temperature sensing probe.

Fig. 5 is a schematic diagram of a simple variation of the structure of fig. 1.

Fig. 6 is a reference diagram for use with the structure of fig. 5.

Fig. 7 is a second preferred sectional view of the autonomous temperature sensing probe.

FIG. 8 is a schematic view of the autonomous temperature sensing probe of FIG. 7 fixed to a kettle body.

Fig. 9 is a third preferred schematic diagram of the autonomous temperature sensing probe.

Fig. 10 is a fourth preferred schematic view of the autonomous temperature sensing probe.

Fig. 11 is a schematic view of a fifth preferred section of the autonomous temperature sensing probe.

FIG. 12 is a sixth preferred view of the autonomous temperature sensing probe.

Fig. 13 is a seventh preferred schematic diagram of the autonomous temperature sensing probe.

Fig. 14 is a schematic view of the operation of the electric ceramic furnace capable of being automatically shut down according to the water temperature.

Fig. 15 is a reference view for use of the autonomous temperature sensing probe of fig. 11.

As shown in the figure, the temperature-sensing device comprises a shell 1, a battery 2, a circuit module 3, a temperature sensor 4, a clamping needle 5, a temperature-sensing metal plate 6, a limiting pin 7, an elastic sealing hook 8, a kettle body 9, a ventilation channel 10, a fixing ring 11, a kettle cover 12, a protruding part 13, an autonomous temperature-sensing probe A, a remote data receiving module 21, a radio transmitting module 31 and a temperature information acquisition module 32.

Detailed Description

As shown in fig. 1 and 2, an autonomous temperature sensing probe comprises a housing, a battery 2, a circuit module 3, and a temperature sensor 4, wherein the battery 2, the circuit module 3, and the temperature sensor are arranged in the housing 1;

the temperature sensor 4 is in direct contact with the inner surface of the shell 1, the temperature sensor 4 is connected with the circuit module 3, the battery 2 is connected with the circuit module 3, the structure of fig. 1 can be adopted, the circuit module 3 is in direct contact and connection with the temperature sensor 4, the battery 2 is in direct contact and connection with the circuit module 3, a changed structure can also be adopted, the battery 2 is in direct contact with the temperature sensor 4, the circuit module 3 is in contact and connection with the battery 2, the circuit module 3 is not in direct contact but connected with the temperature sensor 4, preferably, as shown in fig. 1 and 2, the shell 1 is provided with a clamping pin 5, the shell 1 is provided with a temperature sensing metal block 6, and the temperature sensor 4 is in contact with the temperature sensing metal block 6;

circuit module 3 include radio emission module 31, temperature information acquisition module 32 with temperature sensor 4 intercommunication, radio emission module 31 with temperature information acquisition module 32 intercommunication, the during operation, temperature sensor 4 gathers the casing rather than the contact or directly touches gaseous temperature to transmit data transmission for temperature information acquisition module 32 and by the outside transmission of radio emission module 31, form the system of an independent temperature acquisition and remote data transmission.

The configuration in fig. 12 is different from that in fig. 1 in that the battery 2, the circuit module 3, and the temperature sensor 4 are partially in contact with the temperature sensing metal block 6.

As shown in fig. 3 and 4, an autonomous temperature sensing probe comprises a housing, a battery 2, a circuit module 3 and a temperature sensor 4, wherein the battery 2, the circuit module 3 and the temperature sensor 4 are arranged in the housing 1;

the temperature sensor 4 is embedded in the shell 1, the temperature sensor 4 is in direct contact and connection with the circuit module 3, the battery 2 is in direct contact and connection with the circuit module 3, or the temperature controller 4 is not in direct contact but connected with the circuit module 3, and the battery 2 is arranged between the temperature sensor 4 and the circuit module 3;

and a limiting foot 7 is arranged on the shell 1.

Preferably, as shown in fig. 5, the temperature sensing metal block 6 partially extends out of the housing 1 to form an extending portion 13, the extending portion 13 is a plate, and may also be L-shaped or U-shaped or cylindrical, in order to better hang the autonomous temperature sensing probe on the kettle body 9, the clamping needle 5 is eliminated as compared with fig. 1, the elastic sealing hook 8 is further disposed on the housing 1, the usage method is as shown in fig. 6, the elastic sealing hook 8 is hung on the kettle body 9, so that the extending portion 7 can contact with the gas exhausted from the kettle body 9, and the temperature is conducted to the temperature sensor 4, and the temperature data is emitted outwards through the circuit module 3, as shown in fig. 11, the extending portion 13 is cylindrical, the limiting pin 7 disposed on the housing 1 is a continuous sheet, and the vent hole is disposed on the limiting pin 7, as shown in fig. 15, the autonomous probe can be used as the head of the lid 12 on the kettle body 9, the extending portion 13 penetrates through the lid 12 and is fixed by the fixing member, the steam is discharged through the gap between the fixing member and the lid 12, and the vent hole 12, and the temperature data is collected by the temperature sensor 4 when the temperature data is increased after the temperature sensor 1 is emitted out of the kettle module 3.

Preferably, as shown in fig. 7, an air passage 10 is provided on the housing 1, the temperature sensor 4 is in contact with the inner wall of the air passage 10, when in use, as shown in fig. 8, one end of the air passage 10 extends into the kettle body 9, the air in the kettle body 9 is exhausted through the air passage 10, the temperature sensor 4 acquires the temperature of the wall of the air passage 10, and the temperature sensor 4 transmits the temperature data to the outside through the circuit module 3 after acquiring the temperature data.

Preferably, a fixing ring 11 is sleeved at the extending end of the ventilation channel 10, and the autonomous temperature sensing probe can be fixed in the kettle body 9 through the fixing ring 11.

As shown in fig. 9, the housing 1 is provided with a locking pin 5 and a stopper pin 7, and the stopper pin 7 is made of a different material from the locking pin 5.

Preferably, as shown in fig. 10, the clip 5 and the spacing leg 7 are integrated and are elastic components.

Preferably, as shown in fig. 13, the temperature sensing metal block 6 partially extends out of the housing 1 to form an extension portion 13, the extension portion 13 is U-shaped, and the autonomous temperature sensing probe can be directly hung on the electric ceramic oven through the extension portion 13.

An electric ceramic stove with an automatic temperature sensing probe A and capable of being automatically controlled according to water temperature comprises a kettle body 9 and an electric ceramic stove heater for heating the kettle body 9, wherein an automatic temperature sensing probe A is arranged on a ventilation body channel of the kettle body 9 or an automatic temperature sensing probe A (shown in figure 8) is hung at an opening of a shell 9, a power switch of the electric ceramic stove heater is an electric control switch, and the electric control switch is communicated with a circuit module 3 of the automatic temperature sensing probe A through a front remote data receiving module 21.

The card needle 5 of the autonomous temperature sensing probe A at least partially enters the channel of the vent body.

Preferably, the extension 13 of the temperature-sensing metal plate 6 of the autonomous temperature-sensing probe a is hung on the rim of the vent passage of the pot body 9 or partially blocks the flow of gas, as shown in fig. 6.

As in fig. 14, in operation: the automatic temperature sensing probe A is clamped in a gas passage through a clamping needle 5, a gap is formed between the automatic temperature sensing probe A and a ventilating body passage through a limiting pin 7, an electric ceramic furnace heater is started to heat the kettle body 9 through an electric control switch, after water in the kettle body 9 is heated, gas generated in the ventilating body passage contacts with the gas on a temperature sensing metal plate 6 of the automatic temperature sensing probe A, the heat transfer quantity of the temperature sensing metal plate 6 is transmitted to a temperature controller 4, or the gas is transmitted to a shell 1 of the automatic temperature sensing probe A, after the temperature of the shell 1 rises, the temperature sensor 4 collects the temperature, the temperature reaches a set temperature, the temperature is conducted and is transmitted outwards through a circuit module 3, the circuit module 3 transmits data to a remote data receiving module 21 through a radio transmitting module 31, and the remote data receiving module 21 controls the working state of an electric control circuit.

Claims (10)

1. An autonomous temperature sensing probe is characterized in that: the probe consists of a shell, and a battery, a circuit module and a temperature sensor which are arranged in the shell;

the temperature sensor is directly contacted with or embedded into the shell, the temperature sensor, the circuit module and the battery are respectively and sequentially arranged in the shell, and the temperature sensor and the battery are respectively connected with the circuit module, or the battery is arranged between the temperature sensor and the circuit module, and the temperature sensor and the battery are respectively connected with the circuit module;

the circuit module comprises a radio transmitting module and a temperature information acquisition module, the temperature information acquisition module is communicated with the temperature sensor, and the radio transmitting module is communicated with the temperature information acquisition module.

2. An autonomous temperature-sensing probe according to claim 1, characterized in that: the shell is provided with a temperature sensing metal block, and the temperature sensor is in contact with the temperature sensing metal block.

3. An autonomous temperature-sensing probe according to claim 2, characterized in that: the temperature sensing metal block partially extends out of the shell to form an extending part.

4. An autonomous temperature-sensing probe according to claim 3, characterized in that; the extension part is a plate or is L-shaped or U-shaped.

5. The autonomous temperature sensing probe of claim 1, wherein: the shell is provided with a limiting pin.

6. The autonomous temperature sensing probe of claim 1, wherein: the shell is provided with a ventilation channel, and the temperature sensor is in contact with or embedded into the inner wall of the ventilation channel.

7. An autonomous temperature-sensing probe according to any of claims 1-6, characterized in that: the shell is provided with a clamping pin.

8. An electric ceramic stove using the autonomous temperature sensing probe of any one of claims 1 to 6, which is automatically controlled according to a water temperature, the electric ceramic stove including a pot body and an electric ceramic stove heater for heating the pot body, characterized in that: an independent temperature sensing probe is arranged on the air passage of the kettle body or the independent temperature sensing probe is hung at the opening of the shell, a power switch of the electric ceramic furnace heater is an electric control switch, and the electric control switch is communicated with a radio transmitting module of the independent temperature sensing probe through a front remote data receiving module.

9. The electric ceramic stove capable of being automatically controlled according to water temperature as claimed in claim 8, wherein: the autonomous temperature sensing probe is provided with a clamping needle, and the clamping needle at least partially enters the air passage.

10. The electric ceramic stove capable of being automatically controlled according to water temperature as claimed in claim 8, wherein: the extending part of the temperature sensing metal plate of the autonomous temperature sensing probe is hung on the edge of the channel of the ventilating body on the shell or locally blocks the flow of gas.

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