CN113564032A - Automatic bacterial adding device based on ammonia concentration of degradation tank - Google Patents

Abstract

The invention discloses a strain automatic adding device based on ammonia concentration of a degradation tank, which comprises the degradation tank, a degradation tank cover plate, a valve component, a strain conveying pipe, a strain storage component, an ammonia sensor and a control center, wherein the degradation tank is provided with the degradation tank cover plate which is in sealing fit with the degradation tank, one end of the strain conveying pipe extends into the degradation tank, the other end of the strain conveying pipe is connected with the strain storage component, the strain conveying pipe is provided with the valve component for switching on and off the strain conveying pipe, the ammonia sensor is arranged on the degradation tank cover plate, an ammonia sensor probe on the ammonia sensor extends into the degradation tank, the ammonia sensor is electrically connected with the input end of the control center, and the output end of the control center is electrically connected with the valve component. By the device, microbial strains can be automatically added into the degradation tank, so that the aim of saving cost is fulfilled.

Description

Automatic bacterial adding device based on ammonia concentration of degradation tank

Technical Field

The invention relates to the technical field of toilet excrement treatment, in particular to a strain automatic adding device based on ammonia concentration of a degradation tank.

Background

With the development of society, excrement in the excrement collecting and degrading device (degrading tank) is gradually degraded by microbial strains. At present, the microbial degradation tank on the market can only automatically stir according to a set mode to prevent bacterial dormancy, and whether the bacterial needs to be added on the excrement collecting and degrading device and when the bacterial needs to be added all need manual judgment, so that time and labor are wasted, and a large amount of labor cost is consumed.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provides a strain automatic adding device based on the ammonia gas concentration of a degradation tank.

The purpose of the invention is realized by the following technical scheme:

automatic device that adds of bacterial based on degradation groove ammonia concentration, including degradation groove, degradation groove apron, valve component, bacterial conveyer pipe, bacterial storage subassembly, ammonia sensor and control center, be provided with on the degradation groove with the sealed complex of degradation groove the degradation groove apron, the one end of bacterial conveyer pipe extends to the inside of degradation groove, the other end of bacterial conveyer pipe with the bacterial storage subassembly links to each other, be provided with on the bacterial conveyer pipe and be used for the break-make the bacterial conveyer pipe the valve component, ammonia sensor sets up on the degradation groove apron, ammonia sensor probe on the ammonia sensor extends to the inside of degradation groove, the ammonia sensor with the input electricity of control center is connected, the output of control center with the valve component electricity is connected.

Further, the strain conveying pipe is vertically and fixedly arranged on the degradation tank cover plate in a sealing mode, the lower end of the strain conveying pipe extends into the degradation tank, and the upper end of the strain conveying pipe is connected with the strain storage assembly.

Further, the strain storage assembly comprises a microbial strain storage box and a microbial strain box cover, the microbial strain storage box is connected with the strain conveying pipe, and the microbial strain storage box is provided with the microbial strain box cover matched with the microbial strain storage box.

Further, the control center comprises a power supply and a microcontroller, the ammonia gas sensor is electrically connected with the input end of the microcontroller, the valve assembly is electrically connected with the output end of the microcontroller, and the power supply end of the microcontroller and the valve assembly are both connected with the power supply.

Further, the control center still includes data collection station, data collection station is used for collecting the data that the ammonia sensor detected, and data collection station with the output electricity of microcontroller is connected.

Furthermore, the degradation groove cover plate is provided with a discharge hole, the discharge hole is matched with a discharge hole arranged on the squatting pan, and the discharge hole is positioned right above the discharge hole.

Further, still be provided with the gas discharge port on the degradation groove apron, the inside in degradation groove is provided with stirring heating element.

Further, the valve component comprises a valve component, a connecting pipe, a bracket, a driving motor and a rotating plate, the two ends of the connecting pipe are hermetically connected with the valve parts, the connecting pipe and the strain conveying pipe are coaxially arranged, the valve component at the upper side is connected with the strain storage component through the strain conveying pipe, the valve component at the lower side is connected with the degradation tank through the strain conveying pipe, one end of the bracket is fixedly connected with the middle part of the connecting pipe, the driving motor is fixedly arranged at the other end of the bracket, the middle part of the rotating plate is fixedly arranged on an output shaft of the driving motor, one end of the rotating plate is connected with one valve component, the other end of the rotating plate is connected with the other valve component, and the driving motor is electrically connected with the output end of the control center.

Furthermore, the valve component comprises a valve body, a valve core, a reset spring and a lifting rod, a valve cavity is arranged inside the valve body, the valve core is arranged in the valve cavity and matched with the valve cavity, a through stepped hole is formed in the wall of the valve cavity, the lifting rod is arranged in the stepped hole and matched with the stepped hole, one end of the lifting rod is fixedly connected with the valve core, the other end of the lifting rod is matched with the rotating plate, the reset spring is sleeved on the lifting rod, one end of the reset spring is contacted with the valve core, and the other end of the reset spring is contacted with the bottom of the stepped hole.

Furthermore, a through strip hole is formed in the lifting rod, a roller capable of freely rotating is arranged in the strip hole, the roller is far away from the valve core side, when the length direction of the rotating plate is parallel to the axial lead of the connecting pipe, the two valve components are both in a closed state, and the rollers on the two lifting rods are both in contact with the rotating plate.

The invention has the beneficial effects that:

1) according to the device, whether ammonia in the degradation tank exceeds the standard or not is judged by setting the ammonia sensor at the top of the degradation tank, so that the condition of microbial strains is judged; when ammonia exceeds standard, strains are automatically put in the tank to ensure the number of microorganisms in the degradation tank and the degradation efficiency, and the mode of judging through human experience and manually adding the microorganism strains is eliminated through scientific means, so that the intelligent application degree is greatly improved, and the labor consumption is greatly reduced. Meanwhile, the device plays a data supporting role in discharging time and monitoring the microbial state of the degradation tank.

2) Two valve components are arranged in the valve component, and three switching modes can be realized under the drive of a drive motor, wherein the first mode is that the two valve components are closed; the second is that the upper valve part is opened and the lower valve part is closed; the third is that the upper valve member is closed and the lower valve member is open. The arrangement prevents polluting gas generated in the degradation tank from entering the microbial strain storage box to pollute strains.

Drawings

FIG. 1 is a three-dimensional connection structure diagram of a degradation tank;

FIG. 2 is a side view of the degradation tank;

FIG. 3 is a perspective view of the squatting pan;

FIG. 4 is a control diagram of the present apparatus;

FIG. 5 is a schematic view of the connection structure of the valve assembly;

FIG. 6 is a schematic view showing a connection structure between the rotating plate and the elongated hole;

in the figure, 1-a strain conveying pipe, 2-a valve component, 3-a microorganism strain storage box, 4-a microorganism strain box cover, 5-a connecting pipe, 6-an ammonia gas sensor, 7-a degradation tank, 8-a degradation tank cover plate, 9-an ammonia gas sensor probe, 10-an inlet and outlet hole, 11-a squatting pan, 12-an outlet hole, 13-a gas outlet hole, 14-a stirring and heating component, 15-a bracket, 16-a driving motor, 17-a rotating plate, 18-a valve body, 19-a valve core, 20-a return spring, 21-a lifting rod, 22-a valve cavity, 23-a stepped hole, 24-a long hole and 25-a roller.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the following embodiments, and it should be understood that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without inventive effort based on the embodiments of the present invention, are within the scope of the present invention.

Referring to fig. 1-6, the present invention provides a technical solution:

automatic device that adds of bacterial based on degradation groove ammonia concentration, including degradation groove 7, degradation groove apron 8, valve member 2, bacterial conveyer pipe 1, the subassembly is stored to the bacterial, ammonia sensor 6 and control center, be provided with on the degradation groove 7 with the sealed complex degradation groove apron 8 of degradation groove 7, bacterial conveyer pipe 1's one end extends to the inside of degradation groove 7, bacterial conveyer pipe 1's the other end links to each other with bacterial storage component, be provided with the valve member 2 that is used for break-make bacterial conveyer pipe 1 on the bacterial conveyer pipe 1, ammonia sensor 6 sets up on degradation groove apron 8, ammonia sensor probe 9 on ammonia sensor 6 extends to the inside of degradation groove 7, ammonia sensor 6 is connected with control center's input electricity, control center's output is connected with valve member 2 electricity. Wherein, the ammonia sensor 6 is a sensor in the prior art, and the ammonia sensor 6 is a 0-10V type (special for public toilets) in PR-3002-NH 3. Microbial strains in the strain storage assembly enter the degradation tank 7 through the strain conveying pipe 1, gas in the degradation tank 7 is completely discharged through the gas discharge port 13 due to the sealing arrangement between the degradation tank 7 and the degradation tank cover plate 8, and the gas discharge port 13 is provided with air exhaust equipment. The ammonia gas sensor 6 may be replaced by a hydrogen sulfide sensor, a sensor capable of detecting the number of indole or skatole, or an all-in-one sensor.

Preferably, bacterial conveyer pipe 1 is vertical and sealed fixed setting on degradation groove apron 8, and bacterial conveyer pipe 1's lower extreme extends to the inside of degradation groove 7, and bacterial conveyer pipe 1's upper end is stored the subassembly with the bacterial and is linked to each other. The strain storage component comprises a microbial strain storage box 3 and a microbial strain box cover 4, the microbial strain storage box 3 is connected with the strain conveying pipe 1, and the microbial strain box cover 4 matched with the microbial strain storage box 3 is arranged on the microbial strain storage box 3. Microbial strains storage box 3 is hopper-shaped. Bacterial conveyer pipe 1 is the stereoplasm pipeline, directly supports the bacterial through bacterial conveyer pipe 1 and stores the subassembly, and during microbial strains in the bacterial storage subassembly can enter into degradation groove 7 under the effect of gravity, the microbial strains be prior art, need not set up other power component like this between bacterial storage subassembly and degradation groove 7 and make the microbial strains enter into degradation groove 7.

Preferably, the control center comprises a power supply and a microcontroller, the ammonia gas sensor 6 is electrically connected with the input end of the microcontroller, the valve assembly 2 is electrically connected with the output end of the microcontroller, and the power supply end of the microcontroller and the valve assembly 2 are both connected with the power supply. The control center also comprises a data collector, the data collector is used for collecting data detected by the ammonia gas sensor 6, and the data collector is electrically connected with the output end of the microcontroller. Make this device realize automaticly through control center, when ammonia sensor 6 detects the inside ammonia concentration of degradation groove 7 and reaches 0.5 mg/cubic meter/hour, ammonia sensor 6 gives microcontroller with signal transmission, microcontroller control valve subassembly 2 is opened, microorganism bacterial storage box 3 enters into the inside of degradation groove 7 through bacterial conveyer pipe 1 this moment, when ammonia sensor 6 detects the inside ammonia concentration of degradation groove 7 and is less than 0.2 mg/cubic meter/hour, ammonia sensor 6 gives microcontroller with signal transmission, microcontroller control valve subassembly 2 closes, microorganism bacterial storage box 3 can not enter into the inside of degradation groove 7 through bacterial conveyer pipe 1 this moment. Therefore, the automatic addition control of the microbial strains is realized, and the microbial strains are generally added at a low speed, so that too many microbial strains are prevented from being added at one time. The power supply provides energy for the control center.

Preferably, the degradation tank cover plate 8 is provided with a discharge hole 10, the discharge hole 10 is matched with a discharge hole 12 arranged on the squatting pan 11, and the discharge hole 12 is positioned right above the discharge hole 10. The excrement enters the degradation tank 7 through the drain hole 12 and the drain hole 10, and the excrement is degraded in the degradation tank 7. The degradation tank cover plate 8 is also provided with a gas outlet 13. The degradation tank 7 is provided inside with an agitation heating unit 14. Set up gas vent 13 and make things convenient for the inside gas that produces of discharge degradation groove 7, set up stirring heating element 14 and accelerate degradation inslot portion excrement and urine degradation speed, also make things convenient for the microorganism to mix simultaneously, stirring heating element 14 is prior art.

Valve component 2 includes valve part, connecting pipe 5, support 15, driving motor 16, rotor plate 17, the both ends sealing connection of connecting pipe 5 has valve part, connecting pipe 5 and the coaxial setting of bacterial conveyer pipe 1, and the valve part of upside passes through bacterial conveyer pipe 1 and links to each other with bacterial storage assembly, the valve part of downside passes through bacterial conveyer pipe 1 and links to each other with degradation groove 7, the middle part at connecting pipe 5 is connected to the one end fixed connection of support 15, driving motor 16 is the fixed other end that sets up at support 15, the fixed setting in the middle part of rotor plate 17 is on driving motor 16's output shaft, the one end of rotor plate 17 links to each other with a valve part, the other end of rotor plate 17 links to each other with another valve part, driving motor 16 is connected with control center's output electricity. Wherein the microbial species stored in the species storage assembly is dormant, and in order to prevent the gas generated in the degradation tank 7 from promoting the activation of the dormant microbial species, two valve members are provided in the valve assembly 2, such that at most one of the two valve members is opened during the opening process, thereby effectively preventing the activation of the microbial species. The driving motor 16 is connected with a power supply and also connected with the microcontroller, the driving motor 16 is controlled to rotate forward and backward through the microcontroller, the driving motor 16 drives the rotating plate 17 to rotate forward and backward through forward and backward rotation, so that one valve component is opened, and when the rotating plate 17 is parallel to the connecting pipe 5 in direction, the two valve components are both in a closed state. Under the action of the connecting pipe 5, a certain distance exists between the two valve components, and the installation of the bracket 15 is convenient at the same time, and the bracket is finally used for fixing the driving motor 16. The process of adding the microbial strains in the valve component 2 is that the driving motor 16 firstly rotates forwards, the rotating plate 17 rotates forwards at the moment, the valve component on the upper side is firstly opened through the lifting rod 21, the valve component on the lower side is in a closed state, the microbial strains in the strain storage component enter the connecting pipe 5, then the driving motor 16 rotates backwards, the valve component on the upper side is closed under the most use of the return spring 20 at the moment, the valve component on the lower side is opened, the microbial strains fall into the degradation tank 7, and finally the driving motor 16 is restored to be in an initial position, namely, the two valve components are in a closed state.

Preferably, the valve component comprises a valve body 18, a valve core 19, a return spring 20 and a lifting rod 21, a valve cavity 22 is arranged inside the valve body 18, the valve core 19 is arranged in the valve cavity 22 and matched with the valve cavity 22, a through stepped hole 23 is formed in the wall of the valve cavity 22, the lifting rod 21 is arranged in the stepped hole 23 and matched with the stepped hole 23, one end of the lifting rod 21 is fixedly connected with the valve core 19, the other end of the lifting rod 21 is matched with the rotating plate 17, the return spring 20 is sleeved on the lifting rod 21, one end of the return spring 20 is contacted with the valve core 19, and the other end of the return spring 20 is contacted with the bottom of the stepped hole 23. Wherein, the valve core 19 makes the valve part be in the closed condition all the time under the effect of reset spring 20, and the rotating plate 17 can pull the lifting rod 21 to move when rotating, and the lifting rod 21 moves and can make the valve core 19 move to make the valve body 18 opened, the microorganism bacterial falls under the action of gravity. Typically, a sealing ring is disposed on the inner wall of the valve chamber 22 to further achieve the sealing effect of the valve member and prevent gas from entering.

Preferably, the lifting rod 21 is provided with a through elongated hole 24, a roller 25 capable of freely rotating is arranged in the elongated hole 24, the roller 25 is arranged away from the valve core 19, when the length direction of the rotating plate 17 is parallel to the axial lead of the connecting pipe 5, both valve parts are in a closed state, and the rollers 25 on the two lifting rods 21 are in contact with the rotating plate 17. Because the lifting rod 21 can only move in the horizontal direction, and the rotating plate 17 rotates, the elongated holes 24 and the rollers 25 are arranged, the rollers 25 can effectively reduce the friction force, when the roller 25 in one elongated hole 24 works, one end of the other elongated hole 24 cannot interfere with the rotating plate 17, and interference cannot occur.

The control center can monitor the ammonia index in the interpretation difference in real time to judge whether the ammonia index is within a set value (0.5 mg/cubic meter/hour), and sends out a related control instruction according to corresponding data. The control center judges the estimated putting time according to ammonia gas detection data, operation times, time and other data, and prompts a manager to put microbial strains into the microbial strain storage box in advance through the system, so that the pretreatment prejudgment capability can be effectively realized, and the using efficiency of the toilet and the using environment requirement are improved. The microbial strain storage box is arranged at the upper part of the degradation tank, and the middle of the microbial strain storage box is separated from the degradation tank through a strain conveying pipe and a valve component, so that the moisture-proof problem is effectively solved; the protective cover with the sealing gasket at the top is arranged on the microbial strain storage box, so that the strain storage environment can be effectively protected from being dry while strains are conveniently added; the lower part of the microbial strain storage tank is designed to be an inclined plane, and the strain conveying pipe is connected with the degradation tank to form a right angle or a large angle for installation, so that the strains can be smoothly fed into the degradation tank through the gravity effect; the valve assembly is arranged as a feeding actuating mechanism, can execute corresponding opening and closing actions according to the instruction of a control system, and can set the opening degree and the opening time as required to feed a proper amount of strains as required instead of feeding all strains every time.

The foregoing is illustrative of the preferred embodiments of this invention, and it is to be understood that the invention is not limited to the precise form disclosed herein and that various other combinations, modifications, and environments may be resorted to, falling within the scope of the concept as disclosed herein, either as described above or as apparent to those skilled in the relevant art. And that modifications and variations may be effected by those skilled in the art without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (10)

1. Automatic device that adds of bacterial based on degradation groove ammonia concentration, its characterized in that: including degradation groove (7), degradation groove apron (8), valve member (2), bacterial conveyer pipe (1), bacterial storage component, ammonia sensor (6) and control center, be provided with on degradation groove (7) with degradation groove (7) seal fit degradation groove apron (8), the one end of bacterial conveyer pipe (1) extends to the inside of degradation groove (7), the other end of bacterial conveyer pipe (1) with bacterial storage component links to each other, be provided with on bacterial conveyer pipe (1) and be used for the break-make the valve member (2) of bacterial conveyer pipe (1), ammonia sensor (6) set up on degradation groove apron (8), ammonia sensor probe (9) on ammonia sensor (6) extends to the inside of degradation groove (7), ammonia sensor (6) with control center's input electricity is connected, the output end of the control center is electrically connected with the valve component (2).

2. The automatic bacterial species adding device based on the ammonia gas concentration in the degradation tank as claimed in claim 1, wherein: the strain conveying pipe (1) is vertically and fixedly arranged on the degradation tank cover plate (8) in a sealing mode, the lower end of the strain conveying pipe (1) extends to the interior of the degradation tank (7), and the upper end of the strain conveying pipe (1) is connected with the strain storage assembly.

3. The automatic bacterial species adding device based on the ammonia gas concentration in the degradation tank as claimed in claim 2, wherein: the strain storage assembly comprises a microbial strain storage box (3) and a microbial strain box cover (4), the microbial strain storage box (3) is connected with the strain conveying pipe (1), and the microbial strain storage box (3) is provided with the microbial strain box cover (4) matched with the microbial strain storage box (3).

4. The automatic bacterial species adding device based on the ammonia gas concentration in the degradation tank as claimed in claim 1, 2 or 3, wherein: the control center comprises a power supply and a microcontroller, the ammonia gas sensor (6) is electrically connected with the input end of the microcontroller, the valve assembly (2) is electrically connected with the output end of the microcontroller, and the power supply end of the microcontroller and the valve assembly (2) are connected with the power supply.

5. The automatic bacterial species adding device based on the ammonia gas concentration in the degradation tank as claimed in claim 4, wherein: the control center further comprises a data collector, the data collector is used for collecting data detected by the ammonia gas sensor (6), and the data collector is electrically connected with the output end of the microcontroller.

6. The automatic bacterial species adding device based on the ammonia gas concentration in the degradation tank as claimed in claim 1, 2 or 3, wherein: degradation groove apron (8) are last to be provided with into drain hole (10), enter drain hole (10) and squatting pan (11) and go up drain hole (12) cooperation that sets up, just drain hole (12) are located directly over advancing drain hole (10).

7. The automatic bacterial species adding device based on the ammonia gas concentration in the degradation tank as claimed in claim 1, 2 or 3, wherein: the degradation tank cover plate (8) is further provided with a gas outlet (13), and a stirring and heating assembly (14) is arranged inside the degradation tank (7).

8. The automatic bacterial species adding device based on the ammonia gas concentration in the degradation tank as claimed in claim 1, 2 or 3, wherein: the valve component (2) comprises a valve component, a connecting pipe (5), a support (15), a driving motor (16) and a rotating plate (17), wherein the two ends of the connecting pipe (5) are hermetically connected with the valve component, the connecting pipe (5) and the strain conveying pipe (1) are coaxially arranged, the valve component at the upper side is connected with the strain storage component through the strain conveying pipe (1), the valve component at the lower side is connected with the degradation tank (7) through the strain conveying pipe (1), one end of the support (15) is fixedly connected with the middle part of the connecting pipe (5), the driving motor (16) is fixedly arranged at the other end of the support (15), the middle part of the rotating plate (17) is fixedly arranged on an output shaft of the driving motor (16), one end of the rotating plate (17) is connected with one valve component, the other end of the rotating plate (17) is connected with the other valve component, and the driving motor (16) is electrically connected with the output end of the control center.

9. The automatic bacterial species adding device based on the ammonia gas concentration in the degradation tank as claimed in claim 8, wherein: the valve component comprises a valve body (18), a valve core (19), a return spring (20) and a lifting rod (21), a valve cavity (22) is arranged in the valve body (18), the valve core (19) is arranged in the valve cavity (22) and is matched with the valve cavity (22), a through stepped hole (23) is arranged on the wall of the valve cavity (22), the lifting rod (21) is arranged in the stepped hole (23) and matched with the stepped hole (23), one end of the lifting rod (21) is fixedly connected with the valve core (19), the other end of the lifting rod (21) is matched with the rotating plate (17), the return spring (20) is sleeved on the lifting rod (21), one end of the return spring (20) is contacted with the valve core (19), the other end of the return spring (20) is in contact with the bottom of the stepped hole (23).

10. The automatic bacterial species adding device based on the ammonia gas concentration in the degradation tank as claimed in claim 9, wherein: the valve is characterized in that a through strip hole (24) is formed in the lifting rod (21), a roller (25) capable of rotating freely is arranged in the strip hole (24), the roller (25) is far away from the valve core (19), when the length direction of the rotating plate (17) is parallel to the axial lead of the connecting pipe (5), the two valve components are both in a closed state, and the rollers (25) on the two lifting rods (21) are both in contact with the rotating plate (17).

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