CN209734588U - Electrolysis equipment with concentration detection function - Google Patents

Abstract

the utility model discloses an electrolysis equipment with concentration detection function. This electrolysis equipment, including dissolving chamber and electrolysis chamber, still including the concentration detection device who detects the interior electrolyte solution concentration of dissolving chamber, concentration detection device includes the concentration detection groove with dissolving the chamber intercommunication and the floating body that floats from top to bottom in the concentration detection groove, according to the concentration difference of electrolyte solution, the floating body is the state of floating or sinks in the state of concentration detection tank bottom, concentration detection device still including the detecting element who is used for detecting the floating body state, detecting element sends different detection information according to the different states of floating. When the detection unit sends out the information corresponding to the floating body sinking state, a user knows that the solute needs to be added into the electrolysis equipment through the information, and does not need to self-detect whether the solute quantity is sufficient or not, so that the use of the user is facilitated, and the accuracy of solute quantity detection is improved.

Description

Electrolysis equipment with concentration detection function

Technical Field

The utility model relates to a kitchen tableware food cleaning and sterilizing equipment technical field, concretely relates to electrolysis equipment with concentration detection function.

Background

With the improvement of living standard, the requirements of people on the sanitation and safety of tableware and food materials are higher and higher. The washing of tableware and food materials usually comprises soaking and washing, and sterilization is carried out by means of high temperature or ozone, so as to achieve the effects of washing, pesticide removal, hormone removal and fresh keeping. However, high temperatures can cause damage to some dishes or food materials, ozone can destroy food material nutrition, and treatment and absorption of residual ozone is also a concern. In the prior art, washing devices have appeared which use electrolytes, such as sodium chloride, for cleaning dishes and food materials. When such a washing apparatus is used to wash tableware or food, it is necessary to add an electrolyte to the washing apparatus. In order to add the electrolyte to the washing apparatus, the front side of the washing apparatus is usually connected to an electrolysis device for forming an electrolyte solution and electrolyzing the electrolyte solution to form the electrolyte solution, and the electrolyte solution enters the washing apparatus to wash the dishes or the food materials. In the prior art, during the use process of the electrolysis device, a customer needs to continuously check whether the amount of the solute is sufficient, and add the solute to the electrolysis device under the condition that the amount of the solute is determined to be insufficient. The consumer uses the naked eye or other devices to check the amount of solute by oneself for electrolysis equipment's use is loaded down with trivial details, and the consumer is easy inaccurate to the detection of solute amount moreover, and then leads to the electrolyte solution concentration undersize that forms, can't obtain efficient electrolyte, has influenced the washing effect.

SUMMERY OF THE UTILITY MODEL

The embodiment of the utility model provides an aim at, provide an electrolysis equipment with concentration detection function, no longer need user's self-detection to dissolve the quality whether sufficient, made things convenient for user's use.

in order to solve the technical problem, the utility model provides an electrolysis equipment with concentration detection function, including the dissolving chamber that is used for holding the solute and forms electrolyte solution and the electrolysis chamber that is used for electrolyte solution in order to form electrolyte, still including the concentration detection device who detects dissolving intracavity electrolyte solution concentration, concentration detection device includes the floating body with the concentration detection groove of dissolving the chamber intercommunication and float about in the concentration detection groove, and is different according to electrolyte solution's concentration, the floating body be showy state or stagnate in the state of concentration detection tank bottom, concentration detection device is still including being used for detecting the detecting element of floating body state, detecting element basis different detection information is sent to the different states of floating body.

The embodiment of the utility model provides an electrolysis equipment sets up to including being used for holding the solute and forming the electrolytic solution dissolve the chamber and be used for the electrolytic solution in order to form the electrolytic chamber of electrolyte to, dissolve the solute of intracavity and can not disturb the electrolytic chamber, can obtain better electrolysis effect. Meanwhile, the floating body and the detection unit are matched to detect the concentration of the electrolyte solution, when the floating body is in a floating state, the concentration of the electrolyte solution is higher, and when the floating body is settled at the bottom of the concentration detection tank, the concentration of the electrolyte solution is lower, the solute quantity is insufficient, and the solute needs to be added into the dissolution cavity. Meanwhile, the detection unit sends different detection information according to different states of the floating body, when the detection unit sends information corresponding to the state that the floating body is stagnated at the bottom of the concentration detection tank, a user can know that the solute needs to be added into the electrolysis equipment through the information, the user does not need to self-detect whether the solution quality is sufficient, the use of the user is facilitated, the accuracy of solute quantity detection is improved, and the situation that the concentration of the electrolyte solution is too low due to insufficient solution quality is avoided.

Optionally, be provided with the division board in the dissolution chamber, the division board will the dissolution chamber is cut apart into first minute chamber and second minute chamber, be provided with on the division board and be used for the intercommunication first minute chamber with the through-hole in second minute chamber, hold the solute in the first minute chamber, the concentration detection groove with the second divides the chamber intercommunication.

The concentration detection tank is communicated with the second sub-cavity which does not store the solute, so that the solute can not enter the concentration detection tank, the influence of the solute on the local concentration of the concentration detection tank is avoided, the electrolyte concentration in the concentration detection tank is kept the same as the whole electrolyte concentration, and the floating body can accurately feed back the whole electrolyte concentration.

optionally, the water inlet of the dissolution cavity is arranged in the second sub-cavity, a slow flow plate located at the periphery of the region where the concentration detection tank is located is arranged in the second sub-cavity, and a slow flow hole or a slow flow groove for liquid to pass through is formed in the slow flow plate.

By adopting the structure, the water pressure at the water inlet is higher, and the blocking effect of the slow flow plate is realized, so that the impact force of the liquid entering the concentration detection groove is reduced, the impact of the liquid on the floating body is avoided, the influence of factors except the concentration of the electrolyte solution on the state of the floating body is avoided, the concentration of the electrolyte solution can be accurately fed back by the floating state of the floating body, and the detection accuracy of the floating body on the concentration of the electrolyte is improved.

Optionally, the detecting unit includes an induction module, the induction module includes an emitter for emitting a signal and a receiver for receiving the signal, and when the floating body is in a floating state or a state of being settled at the bottom of the concentration detecting tank, the receiver receives the emitted signal of the emitter and changes.

When the state of the floating body changes, the transmitting signal received by the receiving electrode changes, so that the corresponding state of the floating body can be known according to the transmitting signal, and therefore the detecting unit can send different detection information according to different states of the floating body.

Optionally, the induction module comprises a magnetic substance disposed inside the floating body and a magnetic switch disposed on an outer wall of the dissolution chamber, the magnetic switch is in a first state when the floating body is in a floating state, and the magnetic switch is in a second state when the floating body is in a state of being settled at the bottom of the concentration detection tank; or, the emission pole is the light emitting component, the receiving pole is the light receiving component, the light emitting component with the light receiving component sets up respectively the relative both sides of floating body, when the floating body is the state of floating, the floating body blocks the light receiving component receives the transmission signal of light emitting component, when the floating body sinks when the state of concentration detection tank bottom, the light receiving component receives the transmission signal of light emitting component.

the anti-pollution capacity of the magnetic substance and the magnetic switch is strong, the detection device is not limited by the type of electrolyte solution and the material of the floating body, the magnetic substance is used as the emitting electrode, the magnetic switch is used as the receiving electrode, the anti-pollution capacity of the detection unit is improved, the application range of the detection unit is expanded, and the service life of the detection unit is prolonged.

Adopt light-emitting component and light receiving element cooperation to detect the floating body state, adopt the response module of light signal type, the reaction is rapid, sensitive, can feed back the concentration of department's electrolyte solution more in time, in time remind the user to add the solute.

optionally, the detection unit further comprises a prompting device electrically connected with the sensing module, and when the floating body is settled at the bottom of the concentration detection groove, the prompting device sends prompting information.

By the arrangement mode, when the prompting device 194 sends out the prompting information, a user can know that the solute needs to be added into the dissolving cavity, and the user does not need to detect whether the amount of the solute is sufficient or not, so that the use of the user is facilitated.

Optionally, the electrolyte solution is a sodium chloride solution, and the density of the floating body is 1.02-1.2 mg/mm 3; or the electrolyte solution is a hydrogen chloride solution, and the density of the floating body is 1.02-1.15 mg/mm 3.

Optionally, the concentration detection tank is disposed near a sidewall of the dissolution chamber, and the detection unit is at least partially disposed on the corresponding sidewall.

By the structure, all parts of the detection unit can be concentrated near the side wall, and the electrical connection among all parts of the detection unit is facilitated.

Optionally, a sealing cover is arranged on the top wall of the dissolving cavity, and the sealing cover is connected with the top wall in a screwing, elastic pressing or buckling mode.

Optionally, the concentration detection device further comprises a height measurement unit, the height measurement unit is configured to detect a height of the floating body floating out of the liquid level portion, and the detection unit is further configured to obtain the concentration of the electrolyte solution according to the height of the floating body floating out of the liquid level portion.

By the arrangement mode, a user can know the actual concentration of the electrolyte solution and predict the washing effect of the electrolyte according to the concentration of the electrolyte solution, so that the washing times and the washing time are predicted, and the predictability of the washing effect is improved.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by the practice of the invention. The objectives and other advantages of the invention will be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings.

drawings

The accompanying drawings are included to provide a further understanding of the embodiments of the present invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the embodiments of the invention and not to limit the embodiments of the invention.

FIG. 1 is an electrolytic apparatus with concentration detection function according to an embodiment of the present invention;

FIG. 2 is a view A-A of FIG. 1;

FIG. 3 is a view B-B of FIG. 1;

FIG. 4 is a schematic structural view of an electrolysis apparatus according to an embodiment of the present invention at another angle;

FIG. 5 is a schematic exploded view of the electrolysis apparatus shown in FIG. 1;

FIG. 6 is a schematic view of a bottom cover of the chamber shown in FIG. 5;

FIG. 7 is a schematic structural view of a detecting unit of an electrolysis apparatus according to a first embodiment of the present invention;

FIG. 8 is a schematic view of the middle portion of the chamber of FIG. 5;

FIG. 9 is a B-B view of an electrolytic apparatus according to a second embodiment of the present invention;

FIG. 10 is a schematic view of the structure of a detecting unit of an electrolysis apparatus according to a second embodiment of the present invention.

Description of reference numerals:

10-a dissolution chamber;	11-a first subchamber;	12-a second subchamber;
			13-a separator;	131-a through hole;	14-a water inlet;
17-a concentration detection tank;	171-a floating body;	18-a buffer plate;
			181-a buffer tank;	191-a control panel;	192-an emitter;
193-a receiver electrode;	194-a prompting device;	20-an electrolysis chamber;
			74-side wall;	100-the middle part of the cavity;	200-cavity bottom cover;
300-a cavity top cover;	400-a feeding port;	500-sealing lid.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, embodiments of the present invention will be described in detail below with reference to the accompanying drawings. It should be noted that the embodiments and features of the embodiments in the present application may be arbitrarily combined with each other without conflict.

the present invention will be described in detail below with reference to specific embodiments.

The first embodiment:

FIG. 1 shows an electrolysis apparatus with concentration detection function according to an embodiment of the present invention. Fig. 2 is a view a-a of fig. 1, and fig. 3 is a view B-B of fig. 1. An electrolysis apparatus having a concentration detection function includes a dissolution chamber 10 and an electrolysis chamber 20. The dissolving chamber 10 is used to dissolve a solute to form an electrolyte solution, and the electrolysis chamber 20 is used to electrolyze the electrolyte solution to form an electrolyte solution, as shown in fig. 2 and 3. The electrolysis apparatus further comprises a concentration detection device. The concentration detection device is used for detecting the concentration of the electrolyte solution in the dissolution cavity 10. The concentration detection device includes a concentration detection tank 17 and a floating body 171, the concentration detection tank 17 communicates with the dissolution chamber 10, and the floating body 171 floats up and down in the concentration detection tank as shown in fig. 3. The floating member 171 is in a floating state or a state of being settled at the bottom of the concentration detection tank 17 depending on the concentration of the electrolyte solution. The concentration detection device further comprises a detection unit for detecting the state of the floating body 171, the detection unit emitting different detection information according to different states of the floating body.

The embodiment of the utility model provides an electrolysis equipment sets up to including being used for holding the solute and forming the electrolytic solution dissolve the chamber and be used for the electrolytic solution in order to form the electrolytic chamber of electrolyte to, dissolve the solute of intracavity and can not disturb the electrolytic chamber, can obtain better electrolysis effect.

It is easily understood that, when the concentration of the electrolyte solution is large, the density of the electrolyte solution is large; when the concentration of the electrolyte solution is small, the density of the electrolyte solution is small. Therefore, when the concentration of the electrolyte solution is different, the floating state of the floating body in the dissolution chamber is different. The embodiment of the utility model provides an electrolysis equipment, floating body and detecting element cooperation are used for detecting the concentration of electrolyte solution. When the floating body 171 is in a floating state, it means that the concentration of the electrolyte solution is high, and when the floating body 171 is settled at the bottom of the concentration detection tank, it means that the concentration of the electrolyte solution is low, which means that the amount of the solute is insufficient, and it is necessary to add the solute to the dissolution chamber. Meanwhile, the detection unit sends different detection information according to different states of the floating body 171, when the detection unit sends information corresponding to the state that the floating body is stagnated at the bottom of the concentration detection tank, a user can know that the solute needs to be added into the electrolysis equipment through the information, the user is not required to self-detect whether the solution quality is sufficient, the use of the user is facilitated, the accuracy of solute quantity detection is improved, and the situation that the concentration of the electrolyte solution is too low due to insufficient solution quality is avoided.

in order to ensure that the electrolyte solution concentration is at a high level, in the present embodiment, the floating body is in a floating state when the electrolyte solution reaches a large range; when the concentration of the electrolyte solution is not higher than the preset value, the floating body is settled at the bottom of the concentration detection tank. Here, the larger range may be a concentration range near the saturation concentration. Therefore, when the solute in the dissolving cavity makes the concentration of the electrolyte solution not enough to reach a larger range, the detection unit sends the information of adding the solute, and after the user adds the solute, the electrolyte solution reaches the larger range. Therefore, the electrolyte solution with higher concentration can be obtained all the time, the electrolyte solution is ensured to have higher effective sterilization particle concentration, and the washing effect is improved.

in this embodiment, the electrolyte solution is a sodium chloride solution, and the density of the floating body is 1.02-1.2 mg/mm 3. Hypochlorite particles are generated after the electrolysis of the sodium chloride solution, and the hypochlorite has good sterilization effect and can achieve good washing effect.

In other embodiments, the electrolyte solution can be a hydrogen chloride solution, and the density of the floating body is 1.02-1.15 mg/mm 3.

as shown in fig. 2 and 3, a partition plate 13 is provided in the dissolution chamber 10, and the partition plate 13 divides the dissolution chamber 10 into a first sub-chamber 11 and a second sub-chamber 12. The solute is stored in the first sub-chamber 11, and the concentration detection tank 17 is communicated with the second sub-chamber 12. The partition plate 13 is provided with a through hole 131, and the through hole 131 is used for exchanging water in the first sub-chamber 11 and the second sub-chamber 12.

The concentration detection tank 17 is communicated with the second sub-chamber 12 which does not store the solute, so that the solute can not enter the concentration detection tank 17, the influence of the solute on the local concentration of the concentration detection tank is avoided, the electrolyte concentration in the concentration detection tank is kept the same as the whole electrolyte concentration, and the floating body can accurately feed back the whole electrolyte concentration. In this embodiment, as shown in fig. 2, the inlet of the dissolution chamber 10 is arranged in the second sub-chamber 12. With this configuration, water entering the dissolution chamber can pass from the second subchamber 12 through the through hole 131 into the first subchamber 11. The water inlet 14 pressure is great, and the water that gets into in the second minute chamber 12 also has great pressure to, when the water in the second minute chamber 12 gets into in the first minute chamber 11 through-hole 131 on the division board 13, can produce great impact force upwards to the solute in the first minute chamber 11, the impact force upwards cooperatees with the gravity of solute particle, makes the solute particle be in the motion state of come-up and sinking, promotes the solute and dissolves, accelerates the generation of electrolyte solution, promotes the electrolyte concentration who finally obtains. And, water gets into first minute chamber 11 from second minute chamber 12, can avoid solute particle to block up through-hole 131 under the action of gravity, has reduced the cost of maintenance who dissolves the chamber.

In specific implementations, the isolation plates 13 may be disposed either laterally or longitudinally. When division board 13 transversely sets up, first minute chamber and second divide the chamber to be and distribute from top to bottom, when division board 13 vertically sets up, first minute chamber and second divide the chamber to be and control the distribution, all can reach above the technological effect.

It will be readily understood that in practice the direction of feed is generally from top to bottom, and therefore, in the present embodiment, the partition 13 is arranged transversely, and the first chamber 11 and the second chamber 12 are distributed up and down, i.e. the first chamber 11 is located above the second chamber 12. Due to the arrangement mode, the feeding of the solute is facilitated, in addition, as water is generally filled into the dissolving tank from bottom to top gradually, in the process that the water is filled into the dissolving tank from bottom to top, the water entering the first sub-chamber 11 through the through hole 131 in the second sub-chamber 12 can generate a large upward impact force on the solute in the first sub-chamber 11, an impact stirring effect is generated on the solute, the dissolution of the solute is further accelerated, and the production of the electrolyte solution is further accelerated.

as shown in fig. 3, the groove wall of the concentration detection groove 17 extends upward from the partition plate 13, and the concentration detection groove 17 communicates with the second sub-chamber 12 through a through hole 131. With such a structure, when the floating body is settled at the bottom of the concentration detection tank 17, the floating body does not enter the second sub-chamber 12, so that the influence of the liquid with a large pressure in the second sub-chamber 12 on the state of the floating body can be further avoided. When solution liquid level is higher in dissolving chamber 10, floating body 171 probably contacts electrolysis equipment's roof, in order to avoid taking place adhesion to influence the floating body action behind the floating body 171 contact electrolysis equipment roof, be provided with in the region corresponding with floating body 171 on the roof and block muscle 172, block muscle 172 and be used for blockking floating body 171, avoid floating body 171 and roof direct contact to can avoid floating body and electrolysis equipment roof adhesion, guarantee the normal work of floating body.

fig. 4 is a schematic structural view of another angle of the electrolysis apparatus according to the embodiment of the present invention, and fig. 4 shows a sealing cap. In order to conveniently throw the solute into the dissolving cavity, as shown in fig. 1, a feeding port 400 for throwing the solute is provided on the top wall of the dissolving cavity. The top wall of the dissolving cavity is also provided with a sealing cover 500 for sealing the feeding port, as shown in fig. 4. The sealing cover 500 is connected with the top wall of the dissolving cavity in a screwing, elastic pressing or buckling mode. The top wall of the dissolving cavity is provided with the sealing cover, so that the interference of external substances to the solution in the electrolytic equipment can be avoided.

FIG. 5 is a schematic exploded view of the electrolysis apparatus shown in FIG. 1. As shown in fig. 5, in the present embodiment, the electrolysis device is formed by fastening a middle cavity 100, a bottom cavity cover 200 and a top cavity cover 300, wherein the bottom cavity cover 200 is fastened below the middle cavity 100, and the bottom cavity cover 300 is fastened above the middle cavity 100. Referring to fig. 2, the cavity bottom cover 200 and the cavity cover 300 are respectively provided with longitudinal ribs corresponding to the cavity middle part 100, and the longitudinal ribs on the cavity middle part 100, the cavity bottom cover 200 and the cavity top cover 300 are correspondingly matched with each other to decompose the electrolysis equipment into a dissolution cavity and an electrolysis cavity and limit a water inlet and a water outlet. It is easily understood that, in other implementations, the electrolysis device is not limited to be formed by buckling the middle cavity 100, the bottom cavity 200 and the top cavity 300, and the manufacturing method of the electrolysis device can be designed according to the requirements of the manufacturing process, as long as the structure of the electrolysis device of the embodiment of the present invention can be produced.

fig. 6 is a schematic structural view of the bottom cover of the chamber in fig. 5. The water pressure at the water inlet 14 is high, and in order to avoid the floating body detection error caused by the impact of the water entering from the water inlet 14 on the floating body, as shown in fig. 6, a slow flow plate 18 located at the periphery of the region corresponding to the concentration detection groove is arranged in the second sub-chamber 12, and a slow flow groove 181 for the liquid to pass through is arranged on the slow flow plate 18. In other embodiments, the baffle slots may also be provided as baffle holes.

With such a structure, the water entering from the water inlet 14 enters the region corresponding to the concentration detection tank through the buffer tank 181 of the buffer plate 18, and further enters the concentration detection tank. The blocking effect of the flow buffering plate 18 reduces the impact force of the liquid entering the concentration detection tank, avoids the impact of the liquid on the floating body 171, avoids the influence of factors except the concentration of the electrolyte solution on the state of the floating body 171, enables the floating state of the floating body 171 to accurately feed back the concentration of the electrolyte solution, and improves the detection accuracy of the floating body 171 on the concentration of the electrolyte.

FIG. 7 is a schematic structural view of a detecting unit of an electrolysis apparatus according to a first embodiment of the present invention. In order to enable the detection unit to detect the state of the floating body, the detection unit comprises a sensing module comprising an emitter 192 for emitting a signal and a receiver 193 for receiving a signal. When the float body is in a floating state or sinks to the bottom of the concentration detection cell, the reception electrode 193 receives a change in the transmission signal of the emitter 192. When the state of the floating body changes, the transmitting signal received by the receiving electrode changes, so that the corresponding state of the floating body can be known according to the transmitting signal, and therefore the detecting unit can send different detection information according to different states of the floating body.

in this embodiment, the detection unit includes a control board 191 provided on the outer wall of the dissolution chamber 10, and the receiver electrode 193 is electrically connected to the control board 191.

The emitter 192 includes a magnetic substance disposed inside the floating body 171, and the receiver 193 includes a magnetic switch disposed on an outer wall of the dissolution chamber 10, the magnetic switch being electrically connected to the control board 191. The magnetic switch is arranged on the outer wall of the dissolution chamber 10 at a position corresponding to the floating state of the floating body. When the floating body 171 is in a floating state, the floating body 171 is positioned close to the magnetic switch, and the magnetic switch is in a first state under the action of the magnetic substance, where the first state is a closed state of the magnetic switch. When the float 171 is settled at the bottom of the concentration detection groove, the magnetic switch is far from the float 171, and the magnetic substance cannot act on the magnetic switch, so that the magnetic switch is in the second state, in which the magnetic switch is in the off state. In the present embodiment, the magnetic substance is a magnet provided in the floating body 171.

The anti-pollution capacity of the magnetic substance and the magnetic switch is strong, the detection device is not limited by the type of electrolyte solution and the material of the floating body, the magnetic substance is used as the emitting electrode, the magnetic switch is used as the receiving electrode, the anti-pollution capacity of the detection unit is improved, the application range of the detection unit is expanded, and the service life of the detection unit is prolonged.

The detection unit further comprises a prompting device 194, and the prompting device 194 is electrically connected with the receiving electrode 193 through the control board 191. When the floating body is settled at the bottom of the concentration detection tank, the control board 191 receives a corresponding signal through the receiving electrode 193 and controls the prompting device 194 to send out prompting information. By the arrangement mode, when the prompting device 194 sends out the prompting information, a user can know that the solute needs to be added into the dissolving cavity, and the user does not need to detect whether the amount of the solute is sufficient or not, so that the use of the user is facilitated. The prompting device can select common prompting devices such as an alarm indicating lamp, a buzzer and the like as long as prompting information which can be sensed by a user can be sent.

fig. 8 is a schematic structural view of the middle portion of the chamber in fig. 5. As shown in FIGS. 3 and 8, the concentration detection tank 17 is provided near a side wall 74 of the dissolution chamber 10, and the detection unit is provided at least partially on the side wall 74. In the present embodiment, the control board 191 is provided on the side wall 74. The concentration detection tank 17 is arranged close to the side wall of the dissolution chamber 10, and then, the floating body in the concentration detection tank is also close to the side wall of the dissolution chamber, so that the magnetic switch can be installed on the side wall, and therefore, each part of the detection unit can be concentrated near the side wall, and the electrical connection among each part of the detection unit is facilitated.

Of course, in other embodiments, the concentration detection tank may be disposed at a position away from the side wall of the dissolution chamber. For example, a concentration detection tank is provided at the center position of the concentration detection tank, and a magnetic switch is provided on the side wall of the concentration detection tank, in which case the electrical wiring of the magnetic switch can be connected to the control board through the top wall of the electrolysis apparatus.

it is easily understood that, when the float body floats on the liquid surface of the electrolyte solution, the greater the concentration of the electrolyte solution, the greater the height of the portion of the float body floating from the liquid surface. In this embodiment, the concentration detection apparatus may further include a height measurement unit for detecting a height of the portion of the floating body floating from the liquid surface, the detection unit being electrically connected to the height measurement unit, the detection unit being further configured to obtain the concentration of the electrolyte solution based on the height of the portion of the floating body floating from the liquid surface. Therefore, the user can know the actual concentration of the electrolyte solution and predict the washing effect of the electrolyte according to the concentration of the electrolyte solution so as to predict the washing times and the washing time and improve the predictability of the washing effect.

Second embodiment:

FIG. 9 is a B-B view of an electrolytic apparatus according to a second embodiment of the present invention. FIG. 10 is a schematic view of the structure of a detecting unit of an electrolysis apparatus according to a second embodiment of the present invention. Unlike the first embodiment, in the second embodiment, the emitter 192 is a light emitting element, and the receiver 193 is a light receiving element. The light emitting element and the light receiving element are electrically connected to the control board 191. The light emitting element (i.e., emitter 192) and the light receiving element (i.e., receiver 193) are disposed on opposite sides of the floating body 171, i.e., at two opposite positions on the side walls of the concentration detection grooves, respectively, as shown in fig. 9. When the floating body 171 is in a floating state, the floating body 171 blocks the light receiving element from receiving the transmission signal of the light emitting element, and thus the light receiving element outputs the first detection information; when the floating body 171 sinks at the bottom of the concentration detection groove 17, the light receiving element can receive the emission signal of the light emitting element, and thus, the light receiving element outputs the second detection information.

Adopt light-emitting component and light receiving element cooperation to detect the floating body state, adopt the response module of light signal type, the reaction is rapid, sensitive, can feed back the concentration of department's electrolyte solution more in time, in time remind the user to add the solute.

in order to make the floating body block the light receiving element from receiving the transmission signal of the light emitting element, in this embodiment, the floating body is made of an opaque material.

In the description of the embodiments of the present invention, it should be understood that the terms "middle", "upper", "lower", "front", "rear", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

In the description of the embodiments of the present invention, it should be noted that, unless explicitly stated or limited otherwise, the term "communicate" is to be understood in a broad sense, either directly or indirectly through an intermediary. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

although the embodiments of the present invention have been described above, the description is only for the convenience of understanding the present invention, and the present invention is not limited thereto. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (10)

1. The utility model provides an electrolysis equipment with concentration detection function, is including the dissolving chamber that is used for holding the solute and forms electrolyte solution and the electrolysis chamber that is used for electrolyte solution in order to form electrolyte, its characterized in that, still including the concentration detection device who detects the electrolyte solution concentration in the dissolving chamber, concentration detection device includes the concentration detection groove with dissolving the chamber intercommunication and the floating body that floats from top to bottom in the concentration detection groove, and is different according to the concentration of electrolyte solution, the floating body is floated state or stagnates in the state of concentration detection groove bottom, concentration detection device still including being used for detecting the detecting element of floating body state, detecting element basis the different states of floating body send different detection information.

2. The electrolysis device according to claim 1, wherein a partition plate is arranged in the dissolution cavity, the partition plate divides the dissolution cavity into a first sub-cavity and a second sub-cavity, a through hole for communicating the first sub-cavity with the second sub-cavity is arranged on the partition plate, the first sub-cavity contains the solute, and the concentration detection tank is communicated with the second sub-cavity.

3. the electrolysis device according to claim 2, wherein the water inlet of the dissolution chamber is arranged in the second sub-chamber, a slow flow plate is arranged in the second sub-chamber and is located at the periphery of the area where the concentration detection tank is located, and the slow flow plate is provided with a slow flow hole or a slow flow groove for liquid to pass through.

4. the electrolysis apparatus according to claim 1, wherein the detection unit comprises an induction module, the induction module comprises an emitter for emitting a signal and a receiver for receiving a signal, and the receiver receives the emitter and changes when the floating body is floating or sinks to the bottom of the concentration detection tank.

5. The electrolysis apparatus according to claim 4, wherein the induction module comprises a magnetic substance disposed inside the floating body and a magnetic switch disposed on an outer wall of the dissolution chamber, the magnetic switch being in a first state when the floating body is in a floating state, and being in a second state when the floating body is in a state of settling at a bottom of the concentration detection tank; or, the emission pole is the light emitting component, the receiving pole is the light receiving component, the light emitting component with the light receiving component sets up respectively the relative both sides of floating body, when the floating body is the state of floating, the floating body blocks the light receiving component receives the transmission signal of light emitting component, when the floating body sinks when the state of concentration detection tank bottom, the light receiving component receives the transmission signal of light emitting component.

6. The electrolysis apparatus according to claim 5, wherein the detection unit further comprises a prompting device electrically connected to the sensing module, wherein the prompting device sends a prompting message when the floating body is settled at the bottom of the concentration detection tank.

7. The electrolysis apparatus according to any one of claims 1 to 6, wherein the electrolyte solution is a sodium chloride solution, and the density of the floating body is 1.02 to 1.2mg/mm 3; or the electrolyte solution is a hydrogen chloride solution, and the density of the floating body is 1.02-1.15 mg/mm 3.

8. The electrolysis apparatus according to any one of claims 1 to 6, wherein the concentration detection cell is disposed adjacent to a side wall of the dissolution chamber, the detection unit being disposed at least partially on the respective side wall.

9. The electrolyzing apparatus of any of claims 1-6, wherein a sealing cap is disposed on the top wall of the dissolving chamber, and the sealing cap is connected to the top wall by screwing, snapping, or snapping.

10. The electrolytic apparatus according to claim 1, wherein said concentration detection means further comprises a height measurement unit for detecting a height of the portion of the floating body floating out of the liquid surface, said detection unit further being for obtaining the concentration of the electrolyte solution based on the height of the portion of the floating body floating out of the liquid surface.