CN109179600B - Disinfection powder adding equipment - Google Patents

Abstract

The invention discloses disinfection powder feeding equipment, wherein a box body of the disinfection powder feeding equipment is divided into a storage box, a discharging box and a dissolving box, disinfection powder is stored in the storage box in advance, and then the feeding amount of the disinfection powder into the dissolving box is controlled by a servo motor in the discharging box, so that the automatic discharging of the disinfection powder is realized, the manual feeding times are reduced, the working efficiency is improved, and meanwhile, the harm of the disinfection powder to a human body is greatly reduced; meanwhile, the water level sensor is arranged in the dissolution box to detect the water level in the dissolution box, so that the controller controls the dissolution box to feed water according to the detected liquid level signal, automatic configuration of disinfectant is realized, and the configured disinfectant is quantitatively conveyed out according to the metering pump. The feeding equipment can realize automatic discharging, automatic batching and automatic feeding, reduces manual operation, improves working efficiency, and reduces the contact times of staff and the disinfection powder, thereby reducing the harm of the disinfection powder to human bodies.

Description

Disinfection powder adding equipment

Technical Field

The invention relates to disinfection powder adding equipment.

Background

When in use, the disinfection powder is generally prepared into disinfection solution according to a certain concentration and then disinfects sewage. The existing disinfection powder feeding equipment is inconvenient because of large demand, and needs to be manually and periodically fed with powder for configuration every day, and has low working efficiency; moreover, the disinfection powder has pungent smell and certain toxicity, so that the disinfection powder has great harm to human mucous membrane, is harmful to body health and even causes injury accidents.

Disclosure of Invention

The invention aims to provide disinfection powder adding equipment, which aims to solve the problems of low working efficiency and harm to human bodies of the existing disinfection powder adding equipment.

The technical scheme for solving the technical problems is as follows:

A disinfection powder dosing device comprising: the water inlet device and the water outlet device are respectively connected with the box body, the signal acquisition device is arranged in the box body, and the controller is respectively in communication connection with the water inlet device, the water outlet device and the signal acquisition device;

The box body comprises a storage box, a discharging box and a dissolving box which are sequentially arranged at intervals, wherein a discharging hopper which is connected with the storage box and the dissolving box, a servo motor which is arranged at the outlet of the discharging hopper and used for controlling the discharging of the discharging hopper, and an electric push rod which is connected with a cover plate of the dissolving box are arranged in the discharging box, and signal input ends of the servo motor and the electric push rod are respectively connected with a signal input end of the controller; the signal acquisition device comprises a water level sensor arranged in the dissolution box and a photoelectric sensor arranged on the electric push rod, and signal output ends of the water level sensor and the photoelectric sensor are respectively connected with a signal input end of the controller.

According to the invention, the box body of the feeding equipment is divided into three parts, namely a storage box, a discharging box and a dissolving box, the disinfection powder is stored in the storage box in advance, then the feeding amount of the disinfection powder into the dissolving box is controlled by a servo motor in the discharging box, so that the automatic discharging of the disinfection powder is realized, the existing 'multiple manual feeding' is converted into the discharging mode of 'one manual feeding and batch automatic discharging', the manual feeding times are reduced, the working efficiency is improved, and meanwhile, the harm of the disinfection powder to human bodies is greatly reduced; meanwhile, the water level sensor is arranged in the dissolution box to detect the water level in the dissolution box, so that the controller controls the dissolution box to feed water according to the detected liquid level signal, automatic configuration of disinfectant is realized, and the configured disinfectant is quantitatively conveyed out according to the metering pump.

The automatic feeding equipment can realize automatic discharging, automatic batching and automatic feeding, and can automatically complete the discharging, the dissolving and mixing of the disinfection powder and the feeding of the disinfection solution, thereby reducing the manual operation, improving the working efficiency, reducing the contact times of staff and the disinfection powder and further reducing the harm of the disinfection powder to human bodies.

Further, in a preferred embodiment of the present invention, the water inlet device includes a water inlet pipe and a water inlet valve disposed on the water inlet pipe, the water inlet pipe is communicated with the dissolution tank, and the water inlet valve is in communication connection with the controller.

The controller controls the opening or closing of the water inlet valve according to the water level signal acquired by the water level sensor, so that automatic water addition is realized, and automatic configuration of disinfectant is realized in the dissolving tank. When the water level is low, the controller controls the water inlet valve to open according to the collected water level signal, and water is injected into the dissolving tank; when the water level reaches a high liquid level, the controller controls the water inlet valve to be closed according to the collected water level signal, and water addition is stopped.

Further, in a preferred embodiment of the present invention, the water outlet device includes a water outlet pipe and a metering pump mounted on the water outlet pipe, the water outlet pipe is communicated with the dissolution tank, and the metering pump is in communication connection with the controller.

After the water injection of the dissolving tank is finished, the controller controls the opening of the metering pump to pump quantitative disinfectant into the disinfection tank.

Further, in a preferred embodiment of the present invention, a rotating shaft of the servo motor is transversely disposed below the discharging hopper outlet, a discharging groove corresponding to the discharging hopper outlet is disposed on the rotating shaft, the discharging groove corresponds to a powder inlet disposed on the dissolution box, and a cover plate is disposed at the powder inlet.

According to the invention, the feeding trough is arranged on the rotating shaft of the servo motor, the powder in the storage box is firstly arranged in the feeding trough, and the powder automatically falls into the dissolving box from the feeding trough under the action of gravity when the feeding trough rotates below the rotating shaft along with the rotation of the rotating shaft, and then rotates above the rotating shaft along with the rotating shaft, and the powder falls into the feeding trough from the storage box to be filled, and the above processes are repeated again, so that the feeding is completed.

Further, in a preferred embodiment of the present invention, the water level sensor includes a first water level sensor provided at a lower portion of the dissolution tank and a second water level sensor provided at an upper portion of the dissolution tank.

Transmitting the water shortage state information in the dissolving tank to a controller through a first water level sensor, and controlling the water inlet valve to be opened by the controller; and the second water level sensor is used for transmitting the full water state information in the dissolving tank to the controller, and the controller controls the water inlet valve to be closed.

Further, in a preferred embodiment of the present invention, the controller is a PLC controller.

Further, in a preferred embodiment of the present invention, a vibration mechanism is further disposed in the feeding box, the vibration mechanism includes a vibration rod, one end of the vibration rod is connected with the feeding box, the other end of the vibration rod is suspended and located above a rotating shaft of the servo motor, and an impact column capable of contacting with the vibration rod is disposed on the servo motor.

Further, in a preferred embodiment of the present invention, the disinfection powder adding apparatus further includes a magnetic pump connected to the dissolution tank, and a signal input end of the magnetic pump is connected to a signal output end of the controller.

According to the invention, the magnetic pump is arranged to accelerate dissolution of the disinfection powder, so that the liquid preparation efficiency is improved.

Further, in a preferred embodiment of the present invention, the disinfection powder adding apparatus further includes a liquid storage tank, the liquid storage tank is disposed at a side of the tank body, and the liquid storage tank is communicated with the dissolution tank of the tank body through a water pumping pipe.

The invention has the following beneficial effects:

The invention integrates the processes of discharging, dissolving and mixing the disinfection powder and adding the disinfection solution into one device, the whole process does not need manual operation, the defect that the conventional disinfection powder adding device needs to be periodically added every day is overcome, the labor force is greatly saved, the working efficiency is improved, and the contact times of a human body and the disinfection powder are greatly reduced and the harm of the disinfection powder to the human body is reduced because the original repeated addition is changed into one addition.

Drawings

FIG. 1 is a side view of a disinfection powder addition apparatus according to an embodiment of the present invention;

FIG. 2 is another side view of a disinfection powder addition apparatus according to an embodiment of the present invention;

FIG. 3 is a top view of a disinfection powder addition apparatus according to an embodiment of the present invention;

FIG. 4 is a side view showing the internal structure of a discharging box of the disinfection powder charging device according to the embodiment of the present invention;

FIG. 5 is a side view showing the internal structure of a dissolving tank of the disinfection powder adding device according to the embodiment of the present invention;

FIG. 6 is a schematic view showing a partial structure in a discharging box of a sterilizing powder feeding apparatus according to an embodiment of the present invention;

FIG. 7 is a cross-sectional view showing a partial structure in a discharge box of a sterilizing powder feeding apparatus according to an embodiment of the present invention;

FIG. 8 is a partial schematic block diagram of a disinfection powder addition apparatus according to an embodiment of the present invention;

FIG. 9 is a partial schematic block diagram of a disinfection powder addition apparatus according to an embodiment of the present invention;

FIG. 10 is a schematic view of a sterilizing powder feeding apparatus according to an embodiment of the present invention;

Fig. 11 is a schematic structural view of a disinfection powder feeding apparatus according to an embodiment of the present invention.

In the figure: 100-disinfection powder adding equipment; 10-a box body; 11-a storage box; 12-blanking box; 13-a dissolution tank; 14-a control cabinet; 131-a powder inlet; 132-cover plate; 21-discharging hoppers; 22-a servo motor; 23-a vibration mechanism; 24-an electric push rod; 211-mounting seats; 212-a flange plate; 213-spindle; 214-blanking groove; 215-vibrating bar; 216-strike column; 31-water inlet pipe; 32-a water inlet valve; 33-a water outlet pipe; 34-metering pump; 41-a controller; 42-a first water level sensor; 43-a second water level sensor; 50-magnetic force pump; 60-a liquid storage tank; 61-a water suction pipe.

Detailed Description

The principles and features of the present invention are described below with reference to the drawings, the examples are illustrated for the purpose of illustrating the invention and are not to be construed as limiting the scope of the invention.

Example 1

Referring to fig. 1 to 3, a disinfection powder adding apparatus 100 according to an embodiment of the present invention includes: the device comprises a box body 10, a water inlet device, a water outlet device, a signal acquisition device, a controller 41 and a magnetic pump 50.

Referring to fig. 4 and 5, the tank 10 includes a storage tank 11 at an upper portion, a dissolution tank 13 at a lower portion, and a discharge tank 12 disposed between the storage tank 11 and the dissolution tank 13. The storage box, the discharging box and the dissolving box are sequentially arranged at intervals. The top of the storage box 11 is provided with a feed inlet for adding disinfection powder, and the bottom of the storage box is provided with an opening (not shown) for discharging. The discharging box 12 is internally provided with a discharging hopper 21, a servo motor 22, a vibrating mechanism 23 and an electric push rod 24. The inlet and outlet of the discharge hopper 21 are connected to the storage tank 11 and the dissolution tank 13, respectively. The inlet of the discharge hopper 21 communicates with an opening in the bottom of the storage tank 11. A servo motor 22 and a vibration mechanism 23 are arranged at the outlet of the discharging hopper 21. The dissolving tank 13 is provided with a powder inlet 131 connected to the outlet of the discharge hopper 21. The powder inlet 131 is arranged at the top of the dissolution tank 13. Referring to fig. 6 and 7, a mounting seat 211 is provided below the discharge hopper 21 for fixedly connecting the discharge hopper 21 and the dissolution tank 13. The mounting base 211 has a generally hollow cylindrical structure, and a through hole penetrating the inner cavity is formed in a side wall of the mounting base. The top of the mounting base 211 is connected with the discharge hopper 21 through a flange 212, and the bottom thereof is mounted on the dissolution tank 13 and communicates with the powder inlet 131. The flange 212 and the mounting seat 211 are internally provided with a blanking channel, and the size of the channel is matched with the caliber of an outlet below the discharging hopper 21. The rotating shaft 213 of the servo motor 22 passes through the through hole of the mounting seat 211, and a blanking groove 214 is arranged at the part of the rotating shaft 213 positioned in the mounting seat 211. The discharge chute 214 corresponds to the outlet of the discharge hopper 21. The dissolving tank 13 is provided with a powder inlet 131 corresponding to the discharge chute 214. The opening size of the blanking slot 214 matches the size of the blanking channel. When the rotating shaft 213 rotates, the rotating shaft 213 carries the powder in the discharging groove 214 initially located above to the lower part of the rotating shaft 213, and enters the dissolving tank 13, and the sterilizing powder in the discharging groove 214 is poured once every time the rotating shaft 213 rotates. Thus, the total amount of the discharging is measured by the number of turns of the rotation shaft 213. The relation between the rotation number and the blanking amount can be obtained by testing in advance and fitting data. A cover plate 132 connected with a power output shaft of the electric push rod 24 is arranged at the powder inlet 131. The cover 132 opens or closes the powder inlet 131 by the electric putter 24.

Referring to fig. 6, the vibration mechanism 23 includes a vibration rod 215, one end of the vibration rod 215 is connected to the discharging hopper 21, and the other end of the vibration rod 215 is suspended above the rotating shaft 213 of the servo motor 22. The servo motor 22 is provided with a striking post 216 contactable with the vibrating rod 215. The rotation shaft 213 rotates one turn, and the striking post 216 strikes the vibration rod 215 once to knock down the sterilizing powder deposited on the inner wall of the discharge hopper 21.

Referring to fig. 2 and 3, the water inlet device includes a water inlet pipe 31 communicating with the dissolution tank 13 and a water inlet valve 32 disposed on the water inlet pipe 31. The water inlet pipe 31 is used for injecting clean water into the dissolving tank 13. The water inlet valve 32 is an electric valve, and is provided outside the casing 10. The water outlet means comprises a water outlet pipe 33 communicating with the dissolution tank 13 and a metering pump 34 mounted on the water outlet pipe 33. The water outlet pipe 33 is a conveying pipeline of the disinfectant and is used for conveying the disinfectant prepared in the dissolving tank 13 into a disinfection tank for sewage disinfection treatment. A metering pump 34 is provided outside the tank 10 for delivering a metered amount of sterilizing fluid into the sterilizing chamber.

The signal acquisition means comprise a water level sensor (not shown) for detecting the level of the liquid in the dissolution tank 13 and a photoelectric sensor (not shown) for detecting whether the cover 132 is closed. The photoelectric sensor is provided on the electric putter 24. Specifically, the photoelectric sensor is disposed on the telescopic shaft of the electric putter 24, when the telescopic shaft is extended to the maximum length, the photoelectric sensor senses light, the cover 132 is opened at this time, and when the telescopic shaft is retracted to the minimum length, the photoelectric sensor is retracted into the housing of the electric putter 24, and cannot sense light, and the cover 132 is closed at this time. Therefore, whether the cover plate is opened or closed is judged by whether the photoelectric sensor detects light. Preferably, the number of the photoelectric sensors is 2, and the photoelectric sensors are respectively arranged at two ends of the telescopic shaft. In this embodiment, the photosensor is preferably an E3JK-DS30M1 photosensor.

The controller 41 is a PLC controller 41. Preferably the PLC controller is Schneider TM200CE24T. The controller 41 is provided in the control cabinet 14 at the top of the cabinet 10. The water level sensor includes a first water level sensor 42 provided at a lower portion of the dissolution tank 13 and a second water level sensor 43 provided at an upper portion of the dissolution tank 13. The controller 41 includes a plurality of signal inputs connected to the signal outputs of the first water level sensor 42, the second water level sensor 43, and the photo sensor, respectively. The controller 41 also includes a plurality of signal outputs that are respectively connected to signal inputs of the servo motor 22, the water inlet valve 32, the electric pushrod 24 and the metering pump 34, respectively.

The controller 41 controls the water inlet valve 32 to be opened or closed according to signals from the first water level sensor 42 and the second water level sensor 43. When the water level in the dissolving tank 13 is low or no water exists, the first water level sensor 42 transmits a signal to the controller 41, and the controller 41 controls the water inlet valve 32 to be opened, so that water is injected into the dissolving tank 13. When the dissolution tank 13 is filled with water or the required water amount is reached, the second water level sensor 43 transmits a signal to the controller 41, and the controller 41 controls the water inlet valve 32 to be closed, and water addition is stopped. Thereby realizing the automatic water adding function of the adding equipment.

When the water is added, the controller 41 controls the water inlet valve 32 to be closed, controls the electric push rod 24 to be started, and opens the cover plate 132 at the powder inlet 131.

The controller 41 controls whether the servomotor 22 is operated or not, based on a signal generated by the photosensor. When the controller 41 confirms that the cover plate 132 is opened through the photoelectric sensor, the controller 41 controls the servo motor 22 to start rotating and discharging, disinfection powder in the discharging hopper 21 is added into the dissolution tank 13, when the discharging reaches the expected powder amount, the servo motor 22 stops rotating, meanwhile, the controller 41 controls the electric push rod 24 to work, and the cover plate 132 is confirmed to be closed through the photoelectric sensor. Thereby, the discharging operation is completed.

The adding device of the embodiment of the invention further comprises a magnetic pump 50, and a signal input end of the magnetic pump 50 is connected with a signal output end of the controller 41. When the magnetic pump is in operation, after water injection is finished, the controller 41 controls the servo motor 22 to feed materials and simultaneously controls the magnetic pump 50 to start to operate. The stirring time of the magnetic pump 50 may be preset, and is generally set to 40 minutes. After the sterilizing powder is completely dissolved, the magnetic pump 50 stops working. The magnetic pump 50 is used for dissolving and mixing the sterilizing powder in the dissolving tank 13.

The operation of the present invention will be described below.

Referring to fig. 8, when the first water level sensor 42 detects no water, a signal is transmitted to the controller 41, and the controller 41 controls the water inlet valve 32 to be opened to start water injection into the dissolution tank 13. When the water level reaches a high level, the second water level sensor 43 transmits a signal to the controller 41, and the controller 41 controls the water inlet valve 32 to be closed. At this point, the system prompts dosing. The controller 41 controls the magnetic pump 50 to be started. After the magnetic pump 50 starts to operate, referring to fig. 9, the controller 41 controls the electric push rod 24 to open the cover 132 of the dissolution tank 13. After the controller 41 confirms that the cover plate 132 is opened through the photoelectric sensor, the controller 41 controls the servo motor 22 to rotate, and the blanking is rotated according to the blanking amount preset by the controller 41. When the preset discharging amount is reached, the servo motor 22 stops working, and the controller 41 controls the electric push rod 24 to close the cover plate 132. The magnetic pump 50 continues to operate, and when the stirring time reaches a predetermined value, the magnetic pump 50 stops operating. The controller 41 then controls the start of the metering pump 34 to feed the sterilizing fluid into the sterilizing tank in accordance with the set feed amount. After a lapse of time of addition, the first water level sensor 42 detects the absence of water in the dissolution tank 13 again, and the apparatus stops the addition, thereby completing one dosing cycle. Then, water injection, feeding and adding are carried out according to the process.

Example 2

This embodiment includes all of the features listed in embodiment 1, except that this embodiment also includes a reservoir.

Referring to fig. 10 and 11, the liquid storage tank 60 is disposed beside the tank body 10. The liquid tank 60 communicates with the dissolution tank 13 of the tank body 10 through a water suction pipe 61. The disinfectant in the dissolution tank 13 is pumped to the tank 60 for storage, and then the disinfectant in the tank 60 is pumped to the disinfection tank by a metering pump. In this embodiment, the water outlet pipe is connected to the liquid storage tank 60, and the disinfection solution in the liquid storage tank 60 is transported to the disinfection tank. Compared with the embodiment 1, the embodiment can realize liquid preparation and liquid delivery, and can meet the requirement of continuous large-scale disinfection operation. Example 1 is used on a relatively small scale, typically after dispensing, and is an intermittent operation.

The foregoing description of the preferred embodiments of the invention is not intended to limit the invention to the precise form disclosed, and any such modifications, equivalents, and alternatives falling within the spirit and scope of the invention are intended to be included within the scope of the invention.

Claims (8)

1. A disinfection powder dosing device, comprising: the water inlet device and the water outlet device are respectively connected with the box body, the signal acquisition device is arranged in the box body, and the controller is respectively connected with the water inlet device, the water outlet device and the signal acquisition device in a communication manner; the box body comprises a storage box, a discharging box and a dissolving box which are sequentially arranged at intervals, a discharging hopper connected with the storage box and the dissolving box, a servo motor arranged at the outlet of the discharging hopper and used for controlling the discharging of the discharging hopper, and an electric push rod connected with a cover plate of the dissolving box are arranged in the discharging box, and signal input ends of the servo motor and the electric push rod are respectively connected with signal input ends of the controller; the signal acquisition device comprises a water level sensor arranged in the dissolution tank and a photoelectric sensor arranged on the electric push rod, the signal output ends of the water level sensor and the photoelectric sensor are respectively connected with the signal input end of the controller, a vibration mechanism is also arranged in the discharge tank and comprises a vibration rod, one end of the vibrating rod is connected with the discharging hopper, the other end of the vibrating rod is suspended and located above a rotating shaft of the servo motor, an impact column which can be contacted with the vibrating rod is arranged on the servo motor, the rotating shaft rotates for one circle, the impact column impacts the vibrating rod once, so that disinfection powder deposited on the inner wall of the discharging hopper is knocked down, and the photoelectric sensor is arranged on a telescopic shaft of the electric push rod.

2. The disinfection powder addition apparatus of claim 1, wherein said water inlet means comprises a water inlet pipe and a water inlet valve disposed on said water inlet pipe, said water inlet pipe being in communication with said dissolution tank, said water inlet valve being in communication with said controller.

3. The disinfection powder addition apparatus of claim 1, wherein said water outlet means comprises a water outlet pipe and a metering pump mounted on said water outlet pipe, said water outlet pipe being in communication with said dissolution tank, said metering pump being in communication with said controller.

4. The disinfection powder adding device according to claim 1, wherein a rotating shaft of the servo motor is transversely arranged below a discharging hopper outlet, a discharging groove corresponding to the discharging hopper outlet is arranged on the rotating shaft, the discharging groove corresponds to a powder inlet arranged on the dissolution box, and the cover plate is arranged at the powder inlet.

5. The disinfection powder feeding apparatus according to claim 1, wherein said water level sensor comprises a first water level sensor provided at a lower portion of said dissolution tank and a second water level sensor provided at an upper portion of said dissolution tank.

6. The disinfection powder addition apparatus of claim 1, wherein said controller is a PLC controller.

7. The disinfection powder addition apparatus according to claim 1, further comprising a magnetic pump connected to the dissolution tank, a signal input of the magnetic pump being connected to a signal output of the controller.

8. The disinfection powder addition apparatus of claim 7, further comprising a liquid storage tank, said liquid storage tank being disposed beside said tank, said liquid storage tank being in communication with a dissolution tank of said tank via a water suction pipe.