CN211697635U - Oxygen sensor of washing and drying integrated machine - Google Patents

Abstract

The utility model relates to the field of sensors, in particular to an oxygen sensor of a washing and drying integrated machine, which comprises a first alumina insulation layer, a first zirconia ceramic body, a second zirconia ceramic body, a third zirconia ceramic body, a second alumina insulation layer and a heater which are arranged from top to bottom in sequence, an outer pump electrode is arranged at the upper end of the first alumina insulation layer, an inner pump electrode and a diffusion barrier are arranged between the first zirconia porcelain body and the second zirconia porcelain body, the diffusion barrier is positioned at the lower side of one end of the inner pump electrode, the upper end of the second zirconia ceramic body is provided with a cavity corresponding to the diffusion barrier, the diffusion barrier is arranged in the cavity, one side of the first alumina insulation layer and one side of the first zirconia porcelain body are respectively provided with corresponding conductive holes, and one end of the outer pump electrode and one end of the inner pump electrode respectively correspond to the positions of the conductive holes, and the lower end of the heater is also provided with a heater protective layer. The utility model discloses it is small, oxygen probe power is low moreover, and the energy consumption is little, and the structure is little, and mounting process is simple.

Description

Oxygen sensor of washing and drying integrated machine

Technical Field

The utility model relates to a sensor field indicates a wash and dry by fire all-in-one oxygen sensor especially.

Background

At present, the existing washing machine drying technology mostly adopts constant-temperature timing drying, intelligent drying and the like. In the conventional constant-temperature timing technology, in order to adjust the drying time, the phenomenon that clothes are not dried or damaged is easily caused; intelligent stoving is through perception clothing weight, uses temperature sensor to gather the temperature of air outlet temperature, comdenstion water, drying-machine etc. and handles through the mainboard, and then judges clothing stoving degree. However, in the prior art, the data acquisition and processing have the characteristics of delay, slow response, complex functional structure and high energy consumption.

Disclosure of Invention

In order to solve the problem, the utility model provides a wash and dry by fire all-in-one oxygen sensor solves the clothing and dries by fire not dry, the response is slow, and the energy consumption height problem, through oxygen concentration in the direct measurement washing machine, reachs the degree of drying of clothing according to the relation of oxygen concentration and humidity in the closed space, and then judges whether the clothing is dried by fire, and the reaction is rapid. And the oxygen probe has low power, low energy consumption, small structure and simple installation process.

In order to achieve the above object, the utility model adopts the following technical scheme: the utility model provides a wash and dry by fire all-in-one oxygen sensor, includes from last first alumina insulating layer, the first zirconia porcelain body, the second zirconia porcelain body, the third zirconia porcelain body, second alumina insulating layer and the heater that sets gradually extremely down, first alumina insulating layer upper end is provided with outer pump electrode, be provided with inner pump electrode and diffusion barrier between the first zirconia porcelain body and the second zirconia porcelain body, and the diffusion barrier is located inner pump electrode one end downside, the cavity corresponding with the diffusion barrier is seted up to second zirconia porcelain body upper end, the diffusion barrier sets up in the cavity, one side of the first alumina insulating layer and the first zirconia porcelain body is equipped with the electrically conductive hole that corresponds respectively to outer pump electrode and inner pump electrode's one end corresponds with the electrically conductive hole position respectively, the heater lower extreme still is equipped with the heater protective layer.

Furthermore, a through hole is formed in the other side of the first aluminum oxide insulating layer, and the other end of the outer pump electrode corresponds to the through hole in position.

Further, the first alumina insulation layer and the first zirconia porcelain body are respectively provided with two conductive holes with the same size, and the diameter of each conductive hole is 10-50 mu m.

Wherein the width of the diffusion barrier is 80-250 μm, the thickness of the diffusion barrier is 5-15 μm, the length of the diffusion barrier is 800-3000 μm, and the air permeability of the diffusion barrier is 0-55%.

Wherein the pump voltage of the outer pump electrode and the inner pump electrode is 0.6-1.6V, and the pump current of the outer pump electrode and the inner pump electrode is 50-1000 muA.

The resistance of the heater is 1-5 omega, the heating voltage of the heater is 1-6V, and the working power of the heater is 1-4W.

Furthermore, the first zirconia ceramic body, the second zirconia ceramic body and the third zirconia ceramic body are all ion conductors formed by solid electrolyte.

The beneficial effects of the utility model reside in that: the utility model has the advantages that the signal layer and the heating layer are sintered into a whole by the oxygen sensor of the washing and drying integrated machine, the production cost is low, the production efficiency is high, and the consistency is good; secondly, controlling the size of the diffusion barrier to be within 50uA-1000uA, and detecting the oxygen concentration to be 0% -25%; in addition, the heating voltage is 1-6V, the working power is 1-4W, the power is very low, the size is small, the clothes drying device is suitable for being used in the household appliance industry, the problems that clothes cannot be dried, response is slow, and energy consumption is high are solved, the drying degree of the clothes is obtained through directly measuring the oxygen concentration in the washing machine according to the relation between the oxygen concentration and humidity in a closed space, whether the clothes are dried or not is judged, and the reaction is rapid.

Drawings

Fig. 1 is a schematic structural diagram of the present embodiment.

Fig. 2 is a cross-sectional operational schematic of this particular embodiment.

The reference numbers illustrate: 1. a first alumina insulating layer; 11. a through hole; 2. a first zirconia ceramic body; 3. a second zirconia ceramic body; 31. a cavity; 4. a third zirconia ceramic body; 5. a second aluminum oxide insulating layer; 6. a heater; 61. a heater protection layer; 7. an outer pump electrode; 8. an inner pump electrode; 9. a diffusion barrier; 10. and a conductive hole.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings. The present application may be embodied in many different forms and is not limited to the embodiments described in the present embodiment. The following detailed description is provided to facilitate a more thorough understanding of the present disclosure, and the words used to indicate orientation, top, bottom, left, right, etc. are used solely to describe the illustrated structure in connection with the accompanying figures.

Referring to fig. 1-2, the utility model relates to a washing and drying integrated machine oxygen sensor, which comprises a first alumina insulation layer 1, a first zirconia porcelain body 2, a second zirconia porcelain body 3, a third zirconia porcelain body 4, a second alumina insulation layer 5 and a heater 6, which are arranged from top to bottom in sequence, wherein an outer pump electrode 7 is arranged at the upper end of the first alumina insulation layer 1, an inner pump electrode 8 and a diffusion barrier 9 are arranged between the first zirconia porcelain body 2 and the second zirconia porcelain body 3, the diffusion barrier 9 is positioned at the lower side of one end of the inner pump electrode 8, a cavity 31 corresponding to the diffusion barrier 9 is arranged at the upper end of the second zirconia porcelain body 3, the diffusion barrier 9 is arranged in the cavity 31, one side of the first alumina insulation layer 1 and one side of the first zirconia porcelain body 2 are respectively provided with a corresponding conductive hole 10, and one end of the outer pump electrode 7 and one end of the inner pump electrode 8 respectively correspond to the conductive hole 10, the lower end of the heater 6 is also provided with a heater protective layer 61.

In this embodiment, the other side of the first alumina insulation layer 1 is provided with a through hole 11, and the other end of the outer pump electrode 7 corresponds to the through hole 11. Wherein the first alumina insulation layer 1 and the first zirconia porcelain body 2 are respectively provided with two conductive holes 10 with the same size, and the diameter of the conductive hole 10 is 10-50 μm.

In this embodiment, the first zirconia ceramic body 2, the second zirconia ceramic body 3 and the third zirconia ceramic body 4 are all ion conductors composed of solid electrolyte, wherein the width of the diffusion barrier 9 is 80-250 μm, the thickness is 5-15 μm, the length is 800-3000 μm, and the air permeability of the diffusion barrier 9 is 0-55%; the pump voltage of the outer pump electrode 7 and the inner pump electrode 8 is 0.6-1.6V, and the pump current is 50-1000 muA. Wherein, the resistance of the heater 6 is 1-5 omega, the heating voltage is 1-6V, and the working power is 1-4W.

The working principle is as follows: referring to fig. 2, when a pumping voltage is applied to the zirconia electrolyte pumping unit, electrons obtained from oxygen on the cathode side of the pumping unit generate oxygen ion vacancies in the zirconia solid, and oxygen ions move to the anode under the action of the pumping voltage. Due to the existence of the diffusion barrier 9, the oxygen intake is limited, the pumping oxygen rate is limited in the process of increasing the pumping voltage to pump oxygen, the pumping current gradually saturates and does not increase any more with the increase of the pumping voltage, and the saturation current is called limiting current and is almost in direct proportion to the ambient oxygen concentration. The concentration of oxygen in the closed space is in negative correlation with the humidity, the oxygen dissolved in the water vapor is released along with the reduction of the humidity, the concentration of the oxygen is increased along with the reduction of the humidity value, when the humidity is reduced to a constant value, the concentration of the oxygen is increased to the highest point and is kept stable, and at the moment, the clothes are judged to be dried.

It should be further noted that, applying an operating voltage to the oxygen sensor, generating a signal current value by pumping oxygen, the magnitude of the current changes with the change of the oxygen concentration in the measurement gas. Due to production process errors, the correspondence between the pump current and the oxygen concentration of individual products varies, so that each product needs to be calibrated individually. The type of sensor is determined by its operating voltage and output current range.

In this embodiment, the following formula is applicable to the calibration of all types of sensors for oxygen concentration in all gaseous media.

Wherein, I_s([O₂]) Represents the sensor current, [ O ] in the measured medium₂]Represents the oxygen concentration in the measurement medium expressed in percentage; k denotes a specific constant of the sensor.

In addition, to determine the specific constants of the sensor, the sensor must be placed in a standard gaseous medium of known oxygen concentration (calibrated), and the k value can be calculated by measuring the output current of the sensor according to the following formula.

Wherein k represents a specific constant of the sensor; i is_k([O₂]) An output current representing a known oxygen concentration; o is₂And k represents the calibrated standard gas concentration.

Compared with the prior art, the washing and drying integrated machine oxygen sensor adopts the tape casting process, the multilayer laminating co-firing LTCC/HTCC technology and the like, the signal layer and the heating layer are sintered into a whole, the production cost is low, the production efficiency is high, and the consistency is good; secondly, controlling the size of the diffusion barrier 9 to control the magnitude of the limiting current within 50uA-1000uA, and detecting the oxygen concentration range to be 0% -25%; in addition, the heating voltage is 1-6V, the working power is 1-4W, the power is very low, the volume is small, and the device is suitable for the household appliance industry.

The oxygen sensor of the washing and drying integrated machine solves the problems of no drying of clothes, slow response and high energy consumption, obtains the drying degree of the clothes according to the relation between the oxygen concentration and the humidity in the closed space by directly measuring the oxygen concentration in the washing machine, further judges whether the clothes are dried or not, and has quick response; and the oxygen probe has low power, low energy consumption, small structure and simple installation process.

It should be further noted that the tape casting process, the multi-layer lamination co-firing LTCC/HTCC technology and the like mentioned in this embodiment are conventional processes in the art, and are not described herein again. Unless otherwise specifically stated or limited, the terms "disposed" and the like are to be construed broadly, and the specific meaning of the terms in the present invention can be understood as a matter of context, by those of ordinary skill in the art.

The above embodiments are only for describing the preferred embodiments of the present invention, and are not intended to limit the scope of the present invention, and various modifications and improvements made by the technical solution of the present invention by those skilled in the art are all within the scope of the present invention as defined by the claims.

Claims (7)

1. The utility model provides a wash and dry by fire all-in-one oxygen sensor which characterized in that: include from last first aluminium oxide insulating layer, the first zirconium oxide porcelain body, the second zirconium oxide porcelain body, the third zirconium oxide porcelain body, second aluminium oxide insulating layer and the heater that sets gradually extremely down, first aluminium oxide insulating layer upper end is provided with outer pump electrode, be provided with inner pump electrode and diffusion barrier between the first zirconium oxide porcelain body and the second zirconium oxide porcelain body, and the diffusion barrier is located inner pump electrode one end downside, second zirconium oxide porcelain body upper end is seted up and is hindered corresponding cavity with the diffusion, the diffusion barrier sets up in the cavity, one side of the first aluminium oxide insulating layer and the first zirconium oxide porcelain body is equipped with the electrically conductive hole that corresponds respectively to outer pump electrode and inner pump electrode's one end corresponds with the electrically conductive hole position respectively, the heater lower extreme still is equipped with the heater protective layer.

2. The oxygen sensor of the washing and drying integrated machine according to claim 1, wherein: and a through hole is formed in the other side of the first aluminum oxide insulating layer, and the other end of the outer pump electrode corresponds to the through hole in position.

3. The oxygen sensor of the washing and drying integrated machine according to claim 1, wherein: the first alumina insulation layer and the first zirconia porcelain body are respectively provided with two conductive holes with the same size, and the diameter of each conductive hole is 10-50 mu m.

4. The oxygen sensor of the washing and drying integrated machine according to claim 1, wherein: the width of the diffusion barrier is 80-250 mu m, the thickness of the diffusion barrier is 5-15 mu m, the length of the diffusion barrier is 800-3000 mu m, and the air permeability of the diffusion barrier is 0-55%.

5. The oxygen sensor of the washing and drying integrated machine according to claim 1, wherein: the pump voltage of the outer pump electrode and the pump voltage of the inner pump electrode are 0.6-1.6V, and the pump current of the outer pump electrode and the pump current of the inner pump electrode are 50-1000 muA.

6. The oxygen sensor of the washing and drying integrated machine according to claim 1, wherein: the resistance of the heater is 1-5 omega, the heating voltage of the heater is 1-6V, and the working power of the heater is 1-4W.

7. The oxygen sensor of the washing and drying integrated machine according to claim 1, wherein: the first zirconia ceramic body, the second zirconia ceramic body and the third zirconia ceramic body are all ion conductors formed by solid electrolyte.

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