CN112426039A

CN112426039A - Vertical quantitative machine

Info

Publication number: CN112426039A
Application number: CN202011399695.7A
Authority: CN
Inventors: 李丹; 黄礼; 林国浒; 叶毓林; 李宝锋
Original assignee: Guangzhou Tenggong General Equipment Co ltd
Current assignee: Guangzhou Tenggong General Equipment Co ltd
Priority date: 2020-12-01
Filing date: 2020-12-01
Publication date: 2021-03-02

Abstract

The application relates to a vertical quantifying machine, including the organism and install a plurality of peristaltic pumps in the organism inside, be provided with the identical blow-off groove of quantity and peristaltic pump quantity on the organism, every blow-off groove corresponds and a peristaltic pump intercommunication, is provided with the discharging pipe on the organism, and the quantifying machine still includes MCU module, peristaltic pump control module, regulating module, ejection of compact switch module, water supply module, power module. Through setting up a plurality of peristaltic pump in order to correspond the blowing groove, in order to take out the house steward with the raw materials in the blowing groove under the control of ejection of compact switch module, the raw materials of multiple taste mix at the in-process that the house steward flows, and simultaneously, when the peristaltic pump starts, the water supply module starts, simultaneously to pouring into water in the house steward, drink raw materials mixes the limit flow direction discharging pipe below the promotion of water, and simultaneously, water still has the effect of adjusting allotment drink concentration, so that the beverage that flows from the discharging pipe accords with user's demand more.

Description

Vertical quantitative machine

Technical Field

The application relates to the field of beverage machines, in particular to a vertical quantifying machine.

Background

The existing fruit pulp refers to a pulp product which is prepared by pulping edible parts of fruits or unfermented fruit pulp and contains juice, and the concentration of part of the fruit pulp is higher, so when fruit juice with different tastes is blended, the fruit pulp with different tastes is taken out from different raw material barrels and put into the same drink cup, and then water is added for blending, so that the fruit pulp with various tastes is uniformly mixed, and meanwhile, the fruit pulp is blended to a proper concentration to meet the requirements of customers. However, when beverages are prepared each time, different raw materials need to be taken from different raw material barrels for preparation, the quantity of the raw materials taken out from the raw material barrels is controlled only by the working experience and hand feeling of a preparation worker, the quantity of the raw materials is difficult to be accurately controlled, the proportion of the prepared beverages is inaccurate, and the improvement is needed.

Disclosure of Invention

In order to solve the trouble of user's allotment beverage, this application provides a vertical proportioning machine.

The application provides a vertical quantifying machine, adopts following technical scheme:

a vertical quantifying machine comprises a machine body and a plurality of peristaltic pumps arranged in the machine body, wherein the machine body is provided with discharge tanks the number of which is consistent with that of the peristaltic pumps, each discharge tank is correspondingly communicated with one peristaltic pump, the machine body is provided with a discharge pipe, the discharge ends of the peristaltic pumps are connected with a main pipe, and the main pipe is communicated with the discharge pipe; the quantitative machine still includes:

the MCU module is used for receiving and transmitting signals and transmitting control instructions to other modules of the circuit;

the peristaltic pump control module is coupled with the MCU module and used for controlling the working time of the peristaltic pump and the rotating speed of the peristaltic pump when receiving the instruction of the MCU module;

the adjusting module is coupled with the MCU module and used for adjusting the discharge parameters of the peristaltic pumps;

the discharge switch module is respectively coupled with the MCU module and the peristaltic pump control module to control the peristaltic pumps to discharge materials synchronously;

the water supply module is coupled with the MCU module and is provided with a preset water yield so as to be synchronously started when the discharge switch module is started to supply water to the main pipe;

and the power supply module is respectively coupled with the MCU module, the peristaltic pump control module, the adjusting module, the discharge switch module, the water supply module and the peristaltic pump so as to supply power to the MCU module, the peristaltic pump control module, the adjusting module, the discharge switch module and the water supply module.

Through adopting above-mentioned technical scheme, the drink raw materials of different tastes is added in every charging chute, through setting up a plurality of peristaltic pump in order to correspond the charging chute, in order to take out house steward with the raw materials in the charging chute under ejection of compact switch module's control, the raw materials of multiple taste mix at house steward in-process that flows, and simultaneously, when the peristaltic pump starts, water supply module starts, simultaneously to pouring into water in the house steward, the water convection current that is injected into in the house steward by water supply module has the effect of promotion to the drink raw materials in house steward, drink raw materials mixes limit flow direction discharging pipe below the promotion of water, and simultaneously, water still has the effect of adjusting allotment drink concentration, so that the beverage that flows from the discharging pipe accords with user's demand more. When a user uses the dosing machine, the peristaltic pump is started by operating the discharge switch module, the discharge switch module transmits received information to the MCU module after receiving an instruction of the user, the MCU module controls the peristaltic pump control module and the water supply module according to an input signal so as to control the relevant peristaltic pump to work, so that beverage raw materials in the discharge chute are pumped into the main pipe, and a plurality of raw materials are mixed in the main pipe and then discharged through the discharge pipe; when a user wants to prepare beverages with different tastes, the parameters of the peristaltic pump are adjusted through the adjusting module to control the working time of the peristaltic pump, so that the discharge amount of beverage raw materials is controlled, and the requirements of the beverages with different tastes can be met; after each parameter is adjusted, a user only needs to press one discharging switch module, so that the purpose of one-key discharging can be achieved, and the operation is simple and convenient.

Optionally, the peristaltic pump control module includes a chip of type TB67S109AFTG, and the number of chips is the same as the number of peristaltic pumps.

By adopting the technical scheme, the chip with the model of TB67S109AFTG is a driving chip, and is a driver for controlling the work of the stepping motor, the chip with the model of TB67S109AFTG is internally provided with an error detection circuit and has an error detection signal output function, so that when an error occurs in the peristaltic pump, an alarm signal is sent to the MCU module, and the MCU module can make corresponding actions.

Optionally, the MCU module is electrically connected to an abnormal power-off module for cutting off connection between the peristaltic pump and the power supply when the peristaltic pump is abnormal.

Through adopting above-mentioned technical scheme, through setting up unusual outage module so that the peristaltic pump breaks down, beverage card in the peristaltic pump or when the condition of card material appears in the pipeline, the power supply of MCU module disconnection peristaltic pump to make the difficult condition that damages of appearing of circuit.

Optionally, a feed liquid detection module is installed in the discharging tank, and the feed liquid detection module is connected with the MCU module and is preset with a low water level threshold value to send a prompt signal when the water level in the discharging tank is lower than the low water level threshold value.

Through adopting above-mentioned technical scheme, the raw materials of preparation drink is at the in-process that uses, and the total amount is at continuous change fewly, detects the liquid level of feed liquid in order to detect each discharging groove through setting up feed liquid detection module to the condition in the discharging groove is mastered in real time to the user, when the liquid level highly is less than the low water level threshold value, sends prompt signal, so that the user in time makes measures.

Optionally, the water supply module is connected with a flow detection module, and the flow detection module is connected with the MCU module and transmits the detected water supply amount of the water supply module to the MCU module.

Through adopting above-mentioned technical scheme, flow detection module is used for detecting the water supply of water supply module to more accurate the content of accuse beverage ratio normal water, so that the taste of the beverage of modulation is better, more closes to user's demand.

Optionally, the MCU module is electrically connected to an external memory for storing information received by the MCU module.

Through adopting above-mentioned technical scheme, this scheme is provided with a plurality of peristaltic pump, including the effect of mutually supporting between each module, require great to the memory of MCU module, consequently, through setting up the information that external memory received with the storage MCU module, in order to expand the MCU module, in order to increase the memory of MCU module, and then satisfy the demand of each module during operation, simultaneously, although the MCU module is inside to have configured a plurality of parallel IO interfaces. However, when there are many external devices, the original internal I/O interfaces are not enough, so the MCU module expands the I/O interface chip to meet the input/output requirements.

Optionally, the power supply module is electrically connected to a voltage reduction module for reducing the output voltage of the power supply module.

By adopting the technical scheme, the peristaltic pump and the modules have different optimal voltage requirement values, and the voltage reduction module is arranged to reduce the connection voltage of the quantitative machine so as to meet the requirement of each department load.

Optionally, the peristaltic pump control module is connected with a reversing module for controlling the positive and negative rotation of the peristaltic pump.

Through adopting above-mentioned technical scheme, because of there is the great condition of granule in the raw materials of blowing inslot, lead to and set up the switching-over module to when wasing the peristaltic pump, can control different directions of blade change on the peristaltic pump, so that carry out washing round trip to the peristaltic pump, keep clean state all the time with keeping the peristaltic pump.

In summary, the present application includes at least one of the following beneficial technical effects:

1. through setting up a plurality of peristaltic pump with corresponding discharging tank, in order to take out the interior raw materials of discharging tank to the house steward under the control of ejection of compact switch module, the raw materials of multiple taste mix at the in-process that the house steward flows, and simultaneously, when the peristaltic pump starts, the water supply module starts, simultaneously to pouring into water into in the house steward, the water that is poured into in the house steward by the water supply module has the effect of promoting to the drink raw materials in house steward, drink raw materials mix the limit under the promotion of water and flow to the discharging pipe, and simultaneously, water still has the effect of adjusting allotment drink concentration, so that the beverage that flows out from the discharging pipe accords with user's demand more;

2. the abnormal power-off module is arranged, so that when the peristaltic pump breaks down, beverage is blocked in the peristaltic pump or a pipeline is blocked, the MCU module cuts off the power supply of the peristaltic pump, and the circuit is not easy to damage;

3. the information received by the MCU module is stored through the external memory, so that the MCU module is expanded, the memory of the MCU module is increased, and the requirements of the modules during working are met.

Drawings

FIG. 1 is a schematic view of the overall structure of a dosing machine according to an embodiment of the present application;

FIG. 2 is a schematic view of the internal structure of a dosing machine according to an embodiment of the present application;

FIG. 3 is a schematic diagram of an overall structure of an MCU module and an external memory according to an embodiment of the present application;

FIG. 4 is a schematic diagram of the overall structure of a portion of a peristaltic pump control module and a peristaltic pump in an embodiment of the present application;

FIG. 5 is a schematic diagram of the overall structure of another portion of the peristaltic pump control module and the peristaltic pump in an embodiment of the present application;

FIG. 6 is a schematic diagram illustrating an overall structure of the feed liquid detection module, the water supply module and the abnormal power failure module according to an embodiment of the present disclosure;

FIG. 7 is a schematic diagram of the overall structure of the pressure reduction module and the flow detection module according to an embodiment of the present disclosure;

fig. 8 is a schematic overall structure diagram of a first master switch U1 according to an embodiment of the present application;

FIG. 9 is a schematic diagram of the overall structure of the display and control portion of the nixie tube in an embodiment of the present application;

fig. 10 is a schematic diagram of the overall structure of the second regulation control chip U2 in an embodiment of the present application.

Description of reference numerals: 1. a body; 2. a peristaltic pump; 3. a charging bucket; 4. a cover plate; 5. a ball; 6. a partition plate; 7. a vertical plate; 8. a mounting seat; 9. a machine head; 10. a water filtering box; 11. and (4) heat dissipation holes.

Detailed Description

The present application is described in further detail below with reference to figures 1-10.

The embodiment of the application discloses vertical proportioning machine. Referring to fig. 1 and 2, the quantitative machine includes organism 1 and installs a plurality of peristaltic pumps 2 in organism 1, and open the up end of organism 1 has a plurality of blow-off groove (not shown in the figure), and every blow-off groove all corresponds with a peristaltic pump 2 intercommunication through a connecting pipe, still installs house steward (not shown in the figure) in the organism 1, and the discharge end of peristaltic pump 2 all communicates with house steward, and house steward intercommunication has discharging pipe (not shown in the figure), and the discharge end of discharging pipe stretches out outside organism 1.

Referring to fig. 2, the discharging groove is formed by a feeding barrel 3 on the machine body 1, a cover plate 4 for opening and closing the discharging groove is arranged on an opening end cover of the discharging groove, and a ball 5 for operating the cover plate 4 is fixedly connected to the cover plate 4.

Referring to fig. 2, install baffle 6 in the organism 1, mutually support between baffle 6 and the organism 1 in order to form the space of placing storage bucket 3, whole storage bucket 3 all places in the space that 6 partitions enclose, and the space that 6 partitions enclose is filled with the foamer to be used for keeping warm to the beverage of storage tank in, so that the beverage is difficult for rotting.

Referring to fig. 2, fixedly connected with riser 7 in organism 1, riser 7 is vertical to be placed in

organism

1, and 7 fixedly connected with mount pads 8 of riser, a plurality of peristaltic pump 2 installation are fixed on mount pad 8, and the feed inlet end and the discharge gate of peristaltic pump 2 all set up, and it has the passageway that supplies blow-off groove and 2 intercommunication pipes of peristaltic pump to pass to open between the top of riser 7 and the 1 interior roof of organism. A gap is reserved between the pump head of the peristaltic pump 2 and the vertical plate 7, so that when the peristaltic pump 2 works, heat generated by the peristaltic pump 2 is not easily transmitted to the vertical plate 7.

Referring to fig. 2, the front of organism 1 is provided with aircraft nose 9, the discharging pipe is worn out from aircraft nose 9, filter box 10 is installed to organism 1 bottom, the top surface of filter box 10 is just to the discharge end of discharging pipe, filter box 10 just opens the one side of discharging pipe has a plurality of holes of permeating water, when modulating the drink, place the goblet on filter box 10 opens the one side that has the hole of permeating water, the opening of goblet is just to the discharge end of discharging pipe, water on the goblet wall can be stayed and is stored in filter box 10.

Referring to fig. 2, two sides and the back of the housing 1 are provided with a plurality of heat dissipation holes 11.

The quantitative machine further comprises an MCU module, a peristaltic pump control module, an adjusting module, a discharging switch module, a water supply module and a power supply module.

The MCU module is used for receiving and transmitting signals and transmitting control instructions to other modules of the circuit; the peristaltic pump control module is coupled with the MCU module so as to control the working time of the peristaltic pump 2 and the rotating speed of the peristaltic pump 2 when receiving the instruction of the MCU module; the adjusting module is coupled with the MCU module and is used for adjusting the discharge parameters of each peristaltic pump 2; the discharge switch module is respectively coupled with the MCU module and the peristaltic pump control module to control the peristaltic pumps 2 to discharge synchronously; the water supply module is coupled with the MCU module and is provided with a preset water yield so as to be synchronously started when the discharge switch module is started to supply water to the main pipe; the power supply module is respectively coupled with the MCU module, the peristaltic pump control module, the adjusting module, the discharge switch module, the water supply module and the peristaltic pump 2 so as to supply power to the MCU module, the peristaltic pump control module, the adjusting module, the discharge switch module, the water supply module and the peristaltic pump 2.

The power supply module includes a dc power supply of 24.

Referring to fig. 3, the MCU module includes a fifth chip U5 of model ME32F030, as shown in fig. 3, the fifth chip U5 has peripheral circuits, and the fifth chip U5 is connected to an external memory U10.

Referring to fig. 4 and 5, the peristaltic pump control module includes a first chip U1, a second chip U2, a third chip U3, and a fourth chip U4, all of which are TB67S109 AFTG. The thirty-eighth pin of the first chip U1 is electrically connected with the thirty-fifth pin of the fifth chip U5, the thirty-eighth pin of the second chip U2 is electrically connected with the thirty-second pin of the fifth chip U5, the thirty-eighth pin of the third chip U3 is electrically connected with the twenty-fifth pin of the fifth chip U5, and the thirty-eighth pin of the fourth chip U4 is electrically connected with the twenty-second pin of the fifth chip U5.

Referring to fig. 4, the plurality of peristaltic pumps 2 include a first peristaltic pump, a second peristaltic pump, a third peristaltic pump, and a fourth peristaltic pump, a first pin of a first stepping motor P1 constituting the first peristaltic pump is electrically connected to a tenth pin and an eleventh pin of the first chip U1, a second pin of the first stepping motor P1 is electrically connected to a sixteenth pin and a seventeenth pin of the first chip U1, a third pin of the first stepping motor P1 is electrically connected to a twenty-sixth pin and a twenty-seventh pin of the first chip U1, and a fourth pin of the first stepping motor P1 is electrically connected to a twenty-first pin and a twenty-first pin of the first chip U1, respectively.

Referring to fig. 4, a first pin of a second stepping motor P2 constituting the second peristaltic pump is electrically connected to a tenth pin and an eleventh pin of a second chip U2, respectively, a second pin of the second stepping motor P2 is electrically connected to a sixteenth pin and a seventeenth pin of a second chip U2, respectively, a third pin of the second stepping motor P2 is electrically connected to a twenty-sixth pin and a twenty-seventh pin of a second chip U2, respectively, and a fourth pin of the second stepping motor P2 is electrically connected to a twentieth pin and a twenty-first pin of a second chip U2, respectively.

Referring to fig. 5, a first pin of a third stepping motor P3 constituting the third peristaltic pump is electrically connected to a tenth pin and an eleventh pin of a third chip U3, respectively, a second pin of the third stepping motor P3 is electrically connected to a sixteenth pin and a seventeenth pin of the third chip U3, respectively, a third pin of the third stepping motor P3 is electrically connected to a twenty-sixth pin and a twenty-seventh pin of the third chip U3, respectively, and a fourth pin of the third stepping motor P3 is electrically connected to a twentieth pin and a twenty-first pin of the third chip U3, respectively.

Referring to fig. 5, a first pin of a fourth stepper motor P4 constituting the fourth peristaltic pump is electrically connected to a tenth pin and an eleventh pin of a fourth chip U4, respectively, a second pin of the fourth stepper motor P4 is electrically connected to a sixteenth pin and a seventeenth pin of the fourth chip U4, respectively, a third pin of the fourth stepper motor P4 is electrically connected to a twenty-sixth pin and a twenty-seventh pin of the fourth chip U4, respectively, and a fourth pin of the fourth stepper motor P4 is electrically connected to a twentieth pin and a twenty-first pin of the fourth chip U4, respectively.

Referring to fig. 4 and 5, the first chip U1 is electrically connected with a reversing module for controlling the forward and reverse rotation of the first peristaltic pump.

Referring to fig. 4, the commutation module includes a first resistor R1 and a sixth capacitor C6 connected in series with each other, a fifth capacitor C5 and a second resistor R2 connected in series with each other, a fourth resistor R4 and a third resistor R3 connected in series with each other, a twenty-second resistor R22 and a forty-second resistor R42 connected in series with each other, a twenty-third resistor R23 and a forty-third resistor R43 connected in series with each other, and a twenty-fourth resistor R24 and a forty-fourth resistor R44 connected in series with each other, to control the forward and reverse rotation of the first peristaltic pump, a connection node of the first resistor R1 and the sixth capacitor C6 is electrically connected to a forty-third pin of the first chip U1, the first resistor R1 is connected to a 5V power supply, and the sixth capacitor C6 is grounded; a connecting node of the fifth capacitor C5 and the second resistor R2 is electrically connected with a fourth pin of the first chip U1, the fifth capacitor C5 is connected with a 5V power supply, and the second resistor R2 is grounded; a connecting node of the fourth resistor R4 and the third resistor R3 is connected with a forty-fourth pin of the first chip U1, the fourth resistor R4 is connected with a 5V power supply, and the third resistor R3 is grounded; a connecting node of the twenty-second resistor R22 and the forty-second resistor R42 is connected with a thirty-ninth pin of the first chip U1, the twenty-second resistor R22 is connected with a 5V power supply, and the forty-second resistor R42 is grounded; a connecting node of the twenty-third resistor R23 and the forty-third resistor R43 is connected with a forty-sixth pin of the first chip U1, the twenty-third resistor R23 is connected with a 5V power supply, and the forty-third resistor R43 is grounded; a connecting node of the twenty-fourth resistor R24 and the forty-fourth resistor R44 is electrically connected with a forty-seventh pin of the first chip U1, the twenty-fourth resistor R24 is connected with a 5V power supply, and the forty-fourth resistor R44 is grounded; the commutation module further comprises a fifty-seventh resistor R57 and a fifty-ninth resistor R59 which are connected in series with each other, a connection node of the fifty-seventh resistor R57 and the fifty-ninth resistor R59 is connected with a forty-fourth pin of the fifth chip U5, a fifty-seventh resistor R57 is connected with a 5V power supply, and a fifty-ninth resistor R59 is grounded.

Referring to fig. 4, the commutation module further includes a thirty-first resistor R30 and a twenty-second capacitor C20 connected in series with each other, a seventeenth capacitor C17 and a thirty-third resistor R33 connected in series with each other, a twenty-fifth resistor R25 and a forty-fifth resistor R45 connected in series with each other, a twenty-sixth resistor R26 and a forty-sixth resistor R46 connected in series with each other, a twenty-seventh resistor R27 and a forty-seventh resistor R47 connected in series with each other, a twenty-eighth resistor R28 and a forty-eighth resistor R48 connected in series with each other, a twenty-second capacitor C22 and a fifty-eighth resistor R58 connected in series with each other, a connection node of the thirty-second resistor R30 and the twenty-second capacitor C20 is connected to a forty-third pin of the second chip U595, a connection node of the seventeenth capacitor C17 and the thirty-third resistor R33 is electrically connected to a fourth pin of the second chip U2, a connection node of the fifth resistor R25 and the forty-fifth resistor R2 are electrically connected to the fourth pin of the second chip U2, a connecting node of the twenty-sixth resistor R26 and the forty-sixth resistor R46 is electrically connected with the thirty-ninth pin of the second chip U2, a connecting node of the twenty-seventh resistor R27 and the forty-seventh resistor R47 is connected with the forty-sixth pin of the second chip U2, a connecting node of the twenty-eighth resistor R28 and the forty-eighth resistor R48 is connected with the forty-seventh pin of the second chip U2, and a connecting node of the twenty-second capacitor C22 and the fifty-eighth resistor R58 is electrically connected with the seventh pin of the fifth chip U5.

A thirty-third resistor R30, a seventeenth capacitor C17, a twenty-fifth resistor R25, a twenty-sixth resistor R26, a twenty-seventh resistor R27, a twenty-eighth resistor R28 and a twenty-second capacitor C22 are respectively connected with a 5V power supply; the twentieth capacitor C20, the thirty-third resistor R33, the forty-fifth resistor R45, the forty-sixth resistor R46, the forty-seventh resistor R47, the forty-eighth resistor R48 and the fifty-eighth resistor R58 are all grounded.

Referring to fig. 5, the commutation module further includes a seventeenth resistor R17 and an eighteenth capacitor C18 connected in series with each other, a fifteenth capacitor C15 and a thirty-first resistor R31 connected in series with each other, a thirteenth resistor R13 and a thirty-fourth resistor R34 connected in series with each other, a fourteenth resistor R14 and a thirty-fifth resistor R35 connected in series with each other, a fifteenth resistor R15 and a thirty-sixth resistor R36 connected in series with each other, a sixteenth resistor R16 and a thirty-seventh resistor R37 connected in series with each other, a connection node of the seventeenth resistor R17 and the eighteenth capacitor C18 is connected to a forty-third pin of the second chip U2, a connection node of the fifteenth capacitor C15 and the thirty-first resistor R31 is electrically connected to a fourth pin of the third chip U3, a connection node of the thirteen resistor R13 and the thirty-fourth resistor R34 is electrically connected to a forty-fourth pin of the second chip U2, a thirty-fourth resistor R56 and a thirty-fourth resistor R35 are electrically connected to a ninth pin of the ninth chip U8653, the connection node of the fifteenth resistor R15 and the thirty-sixth resistor R36 is connected with the forty-sixth pin of the second chip U2, and the connection node of the sixteenth resistor R16 and the thirty-seventh resistor R37 is connected with the forty-seventh pin of the second chip U2.

A seventeenth resistor R17, a fifteenth capacitor C15, a thirteenth resistor R13, a fourteenth resistor R14, a fifteenth resistor R15 and a sixteenth resistor R16 are respectively connected with a 5V power supply; an eighteenth capacitor C18, a thirty-first resistor R31, a thirty-fourth resistor R34, a thirty-fifth resistor R35, a thirty-sixth resistor R36 and a thirty-seventh resistor R37.

Referring to fig. 5, the commutation module further includes a twenty-ninth resistor R29 and a nineteenth capacitor C19 connected in series with each other, a sixteenth capacitor C16 and a thirty-second resistor R32 connected in series with each other, an eighteenth resistor R18 and a thirty-eighth resistor R38 connected in series with each other, a nineteenth resistor R19 and a thirty-ninth resistor R39 connected in series with each other, a twentieth resistor R20 and a forty resistor R40 connected in series with each other, and a twenty-first resistor R21 and a forty-first resistor R41 connected in series with each other, a connection node of the twenty-ninth resistor R29 and the nineteenth capacitor C19 is connected to a forty-third pin of the second chip U2, a connection node of the sixteenth capacitor C16 and the thirty-second resistor R32 is electrically connected to a fourth pin of the fourth chip U4, a connection node of the eighteenth resistor R18 and the thirty-eighth resistor R38 is electrically connected to a thirty-third pin 695 of the fourth chip U2, a thirty-eighth resistor R8653 and a thirty-ninth pin 828653 are electrically connected to a ninth pin of the ninth chip U39, the connecting node of the twentieth resistor R20 and the forty-fourth resistor R40 is connected with the forty-sixth pin of the second chip U2, and the connecting node of the twenty-first resistor R21 and the forty-first resistor R41 is connected with the forty-seventh pin of the second chip U2.

A twenty-ninth resistor R29, a sixteenth capacitor C16, an eighteenth resistor R18, a nineteenth resistor R19, a twentieth resistor R20 and a twenty-first resistor R21 are respectively connected with a 5V power supply; a nineteenth capacitor C19, a thirty-second resistor R32, a thirty-eighth resistor R38, a thirty-ninth resistor R39, a forty-fourth resistor R40 and a forty-first resistor R41.

Referring to fig. 6, the water supply module includes a sixth solenoid valve terminal P6 connected to the solenoid valve and a seventh water pump terminal P7 connected to the water pump, and the sixth solenoid valve terminal P6 and the seventh water pump terminal P7 are connected to the solenoid valve and the water pump, respectively, to supply clean water into the manifold. A second terminal of a sixth solenoid valve terminal P6 is connected with a 24V direct current DC24V, a second pin of a sixth solenoid valve terminal P6 is connected with a second diode D2 in a reverse series mode, a cathode of the second diode D2 is connected with a first pin of a sixth solenoid valve terminal P6, a first pin of a sixth solenoid valve terminal P6 is connected with a third triode Q3 with an enhanced N channel, a drain of the third triode Q3 is connected with a first pin of a sixth solenoid valve terminal P6, a source of the third triode Q3 is grounded, and a gate of the third triode Q3 is grounded after sequentially passing through a fifty-third resistor R53 and a fifty-fourth resistor R54. The connection node of the fifty-third resistor R53 and the fifty-fourth resistor R54 is connected to the fortieth pin of the fifth chip U5.

Referring to fig. 6, a second terminal of the seventh water pump terminal P7 is connected to a 24V DC power supply DC24V, a second pin of the seventh water pump terminal P7 is connected in series and in reverse to a third diode D3, a cathode of the third diode D3 is connected to a first pin of the seventh water pump terminal P7, a first pin of the seventh water pump terminal P7 is connected to a fourth triode Q4 with an enhanced N-channel, a drain of the fourth triode Q4 is connected to a first pin of the seventh water pump terminal P7, a source of the fourth triode Q4 is grounded, and a gate of the fourth triode Q4 is grounded after passing through a fifty-five resistor R55 and a fifty-sixth resistor R56 in sequence. A connection node of the fifty-fifth resistor R55 and the fifty-sixth resistor R56 is connected to a thirty-ninth pin of the fifth chip U5.

Referring to fig. 6, the abnormal power down module includes a fifth terminal P5, a first pin of the fifth terminal P5 is grounded, a second pin of the fifth terminal P5 is connected to an enhanced P-channel first transistor Q1, a drain of the first transistor Q1 is connected to a second pin of the fifth terminal P5, a source of the first transistor Q1 is connected to the DC24V terminal, a forty-ninth resistor R49 is connected between a gate and a drain of the first transistor Q1, a gate of the first transistor Q1 is connected to an NPN-type second transistor Q2 through a fifty-resistor R50, a collector of the second transistor Q2 is connected to a fifty-resistor R50, an emitter of the second transistor Q2 is grounded, a base of the second transistor Q2 is grounded through a fifty-second resistor R52, and a base of the second transistor Q2 is connected to a thirty-sixth pin of the fifth chip U5 through the first resistor R51. The abnormal power-off module receives a signal transmitted by the fifth chip U5, so that when any one peristaltic pump 2 has a problem, the abnormal power-off module cuts off the power supply of the peristaltic pump 2 to protect the circuit.

Referring to fig. 6, the feed liquid detection module includes a twelfth water level terminal P12, a thirteenth water level terminal P13, a fourteenth water level terminal P14 and a fifteenth water level terminal P15, a first pin of the twelfth water level terminal P12 is connected to an NPN-type sixth triode Q6 through a sixty-third resistor R63, a base of the sixth triode Q6 is connected to the sixty-third resistor R63, an emitter of the sixth triode Q6 is grounded, and a collector of the sixth triode Q6 is connected to a sixth pin of a fifth chip U5; a second pin of the twelfth water level terminal P12 is connected with an NPN-type fifth triode Q5 through a sixty-second resistor R62, a base of the fifth triode Q5 is connected with a sixty-second resistor R62, an emitter of the fifth triode Q5 is grounded, and a collector of the fifth triode Q5 is connected with a fourth pin of the fifth chip U5; a third pin of the twelfth water level terminal P12 is connected to an emitter of an NPN-type ninth triode Q9, a collector of the ninth triode Q9 is connected to the 5V power supply, and a base of the ninth triode Q9 is connected to a forty-fifth pin of the fifth chip U5 through a seventy-first resistor.

Referring to fig. 6, a second pin of the thirteenth water terminal P13 is connected to an NPN-type seventh transistor Q7 through a sixty-sixth resistor R66, a base of the seventh transistor Q7 is connected to the sixty-sixth resistor R66, an emitter of the seventh transistor Q7 is grounded, and a collector of the seventh transistor Q7 is connected to a nineteenth pin of the fifth chip U5; a first pin of the thirteenth water level terminal P13 is connected with an NPN-type eighth triode Q8 through a sixty-eight resistor R68, a base of the eighth triode Q8 is connected with a sixty-eight resistor R68, an emitter of the eighth triode Q8 is grounded, and a collector of the eighth triode Q8 is connected with an eighteenth pin of the fifth chip U5; a third pin of the thirteenth water terminal P13 is connected to an emitter of an NPN-type ninth transistor Q9.

Referring to fig. 6, a second pin of the fourteenth water level terminal P14 is connected to a thirteenth diode Q10 of NPN type through a seventy-second resistor R72, a base of the thirteenth diode Q10 is connected to the seventy-second resistor R72, an emitter of the thirteenth diode Q10 is grounded, and a collector of the thirteenth diode Q10 is connected to a sixteenth pin of the fifth chip U5; a first pin of the fourteenth water level terminal P14 is connected with an NPN-type eleventh triode Q11 through a seventy-third resistor R73, a base of the eleventh triode Q11 is connected with a seventy-third resistor R73, an emitter of the eleventh triode Q11 is grounded, and a collector of the eleventh triode Q11 is connected with a seventeenth pin of the fifth chip U5; a third pin of the fourteenth water terminal P14 is connected to an emitter of an NPN-type ninth transistor Q9.

Referring to fig. 6, a second pin of the fifteenth water level terminal P15 is connected to an NPN-type twelfth triode Q12 through a seventy-fourth resistor R74, a base of the twelfth triode Q12 is connected to the seventy-fourth resistor R74, an emitter of the twelfth triode Q12 is grounded, and a collector of the twelfth triode Q12 is connected to a fourteenth pin of the fifth chip U5; a first pin of the fifteenth water level terminal P15 is connected with an NPN-type thirteenth triode Q13 through a seventy-fifth resistor R75, a base of the thirteenth triode Q13 is connected with a seventy-fifth resistor R75, an emitter of the thirteenth triode Q13 is grounded, and a collector of the thirteenth triode Q13 is connected with a fifteenth pin of the fifth chip U5; a third pin of the fifteenth water terminal P15 is connected to an emitter of an NPN-type ninth transistor Q9.

Referring to fig. 7, the MCU module is electrically connected to a voltage step-down module for stepping down the output voltage of the power supply module.

Referring to fig. 7, the buck module includes a sixth chip U6 of model JW5015A, a first pin of the sixth chip U6 is grounded after passing through a first inductor L1 and a twenty-fifth capacitor C25, a first pin of the sixth chip U6 is grounded after passing through a first inductor L1 and a twenty-seventh capacitor C27, a first pin of the sixth chip U6 is grounded after passing through a first inductor L1 and a twenty-sixth capacitor C26, a first pin of the sixth chip U6 is grounded through a first inductor L1, the sixty-fourth resistor R64 and the sixty-fifth resistor R65 are grounded, the fourth pin of the sixth chip U6 is connected to the connection node of the sixty-fourth resistor R64 and the sixty-fifth resistor R65, the second pin of the sixth chip U6 is connected with the connection node of the first inductor L1 and the twenty-sixth capacitor C26 through the twenty-eighth capacitor C28, the 12V voltage is output at the connection node of the twenty-eighth capacitor C28 and the first inductor L1, and the third pin of the sixth chip U6 is grounded through the twenty-ninth capacitor C29. The eighth pin of the sixth chip U6 is connected in series with the fourth diode D4 in the reverse direction and then connected with the terminal of the DC24V, the eighth pin of the sixth chip U6 is grounded through the twenty-fourth large capacitor C24, and the seventh pin of the sixth chip U6 is connected with the eighth pin through the sixty-first resistor R61.

Referring to fig. 7, the voltage dropping module further includes a seventh chip U7 of type JW5052C, a first pin of the seventh chip U7 is sequentially grounded through a thirty-third capacitor C33, a second inductor L2 and a thirty-third capacitor C30, a sixth pin of the seventh chip U7 is connected to a connection node of the thirty-third capacitor C33 and the second inductor L2, a first pin of the seventh chip U7 is sequentially grounded through the thirty-third capacitor C33, the back of the thirty-first capacitor C31 is grounded, the first pin of the seventh chip U7 is grounded after passing through a thirty-third capacitor C33 and a thirty-second capacitor C32 in sequence, the second pin of the seventh chip U7 is grounded, the third pin of the seventh chip U7 is grounded after passing through a sixty-seventh resistor R67, the third pin of the seventh chip U7 outputs 5V voltage after passing through a seventy resistor R70, the fifth pin of the seventh chip U7 is grounded after passing through a thirty-fourth capacitor C34, and the fourth pin of the seventh chip U7 is connected with the fifth pin after passing through a sixty-ninth resistor R69.

Referring to fig. 7, the fifth chip U5 is electrically connected to a flow detection module, and the flow detection module transmits the detected water output of the water pump to the fifth chip U5. The flow detection module comprises a first eleventh flow sensor P11, a third pin of the first eleventh flow sensor P11 is connected with a voltage of 5V, a second pin of the first eleventh flow sensor P11 is grounded through a sixty resistor R60 and a twenty-third capacitor C23, and a first pin of the first eleventh flow sensor P11 is grounded.

Referring to fig. 7, the discharging switch module includes a ninth key board P9, a first pin of the ninth key board P9 is connected to a 5V power supply, a second pin of the ninth key board P9 is connected to a tenth pin of a fifth chip U5, and a third pin of the ninth key board P9 is connected to an eleventh pin of the fifth chip.

Referring to fig. 8, the discharging switch module further includes a fifth chip U connected to a first master switch U1 with an AIP650 model, a fifth pin of the first master switch U1 is sequentially connected to a fourth light emitting diode D4, a third light emitting diode D3, a second light emitting diode D2 and a first light emitting diode D1, an anode of the first light emitting diode D1 is connected to a twelfth pin of the first master switch U1, an anode of the second light emitting diode D2 is connected to a thirteenth pin of the first master switch U1, an anode of the third light emitting diode D3 is connected to a fourteenth pin of the first master switch U1, and an anode of the fourth light emitting diode D4 is connected to a fifteenth pin of the first master switch U1. A seventh pin of the first master switch U1 is sequentially connected with an eighth light emitting diode D8, a seventh light emitting diode D7, a sixth light emitting diode D6 and a fifth light emitting diode D5, an anode of the fifth light emitting diode D5 is connected with a second pin of the second button P2, an anode of the sixth light emitting diode D6 is connected with a second pin of the third button P3, an anode of the seventh light emitting diode D7 is connected with a second pin of the fourth button P4, and an anode of the eighth light emitting diode D8 is connected with a second pin of the fifth button P5. The first pin of the second button P2 is connected with the first pin of the third button P3, the connecting node of the first pin of the second button P2 and the first pin of the third button P3 is connected with the fifth pin of the first master switch U1, and the first pin of the fourth button P4 and the first pin of the fifth button P5 are connected and then connected with the seventh pin of the first master switch U1. An anode of the fifth light emitting diode D5 is connected to the twelfth pin of the first master switch U1, an anode of the sixth light emitting diode D6 is connected to the thirteenth pin of the first master switch U1, an anode of the seventh light emitting diode D7 is connected to the fourteenth pin of the first master switch U1, and an eighth light emitting diode D8 is connected to the fifteenth pin of the first master switch U1. The second button P2 is a discharge switch of the quantitative machine, and when the second button P2 is pressed, the four peristaltic pumps synchronously act according to preset parameters to realize discharge. The first light-emitting diode D1 and the fifth light-emitting diode D5 are lighted up and respectively correspond to the situation that the material in the discharging tank is lower than the preset value and the discharging tank is empty.

The third button P3, the fourth button P4 and the fifth button P5 are expansion button switches, different preset parameter values are set for the peristaltic pump, and the material can be discharged in a one-key mode by controlling the third button P3, the fourth button P4 or the fifth button P5.

Referring to fig. 8, the second pin of the first master switch U1 is further connected to a first key board P1, the second pin of the first master switch U1 is connected to the third pin of the first key board P1, the third pin of the first master switch U1 is connected to the second pin of the first key board P1, and the fourth pin of the first master switch U1 is connected to the first pin of the first key board P1. The fourth pin of the first master switch U1 is connected to ground. The fourth pin of first keypad P1 is tied to a voltage of 5V.

Referring to fig. 9, the quantitative machine further comprises a first nixie tube DS1 for displaying the water outlet quantity of the water pump, a second nixie tube DS2 for displaying the material outlet quantity of the first peristaltic pump, a third nixie tube DS3 for displaying the material outlet quantity of the second peristaltic pump, a fourth nixie tube DS4 for displaying the material outlet quantity of the third peristaltic pump, and a fifth nixie tube DS5 for displaying the material outlet quantity of the fourth peristaltic pump, wherein the first nixie tube DS1 is electrically connected with a second numerical control chip U2 with the model of AIP650, and the second nixie tube DS2, the third nixie tube DS3 and the fourth nixie tube DS4 are connected with a third numerical control chip U3 with the model of AIP 1640.

Referring to fig. 9, the first pin, the second pin, the third pin, the fourth pin, the fifth pin, the sixth pin, the seventh pin, the eighth pin, the ninth pin, the tenth pin, the eleventh pin and the twelfth pin of the first nixie tube DS1 are respectively connected to the thirteenth pin, the twelfth pin, the sixteenth pin, the eleventh pin, the fifteenth pin, the first pin, the ninth pin, the fifth pin, the sixth pin, the fourteenth pin, the eighth pin and the seventh pin of the second digital control chip U2. The numerical value displayed by the first nixie tube DS1 is controlled by the second digital control chip U2.

Referring to fig. 9, a first pin, a second pin, a third pin, a fourth pin, a fifth pin, a sixth pin, a seventh pin, an eighth pin, a ninth pin, a tenth pin, an eleventh pin, and a twelfth pin of the second digital code tube DS2 are respectively connected to a thirteenth pin, a twelfth pin, a sixteenth pin, an eleventh pin, a fifteenth pin, an eighteenth pin, a tenth pin, a nineteenth pin, a twentieth pin, a fourteenth pin, a ninth pin, and a twenty-first pin of the third digital control chip U3.

Referring to fig. 9, the first pin, the second pin, the third pin, the fourth pin, the fifth pin, the sixth pin, the seventh pin, the eighth pin, the ninth pin, the tenth pin, the eleventh pin and the twelfth pin of the third nixie tube DS3 are respectively connected to the thirteenth pin, the twelfth pin, the sixteenth pin, the eleventh pin, the fifteenth pin, the twenty-second pin, the tenth pin, the twenty-third pin, the twenty-fourth pin, the fourteenth pin, the ninth pin and the twenty-fifth pin of the third digital control chip U3.

Referring to fig. 9, a first pin, a second pin, a third pin, a fourth pin, a fifth pin, a sixth pin, a seventh pin, an eighth pin, a ninth pin, a tenth pin, an eleventh pin, and a twelfth pin of the fourth nixie tube DS4 are respectively connected to a thirteenth pin, a twelfth pin, a sixteenth pin, an eleventh pin, a fifteenth pin, a twenty-sixth pin, a tenth pin, a twenty-seventh pin, a twenty-eighth pin, a fourteenth pin, a ninth pin, and a first pin of the third digital control chip U3.

Referring to fig. 9, the first pin, the second pin, the third pin, the fourth pin, the fifth pin, the sixth pin, the seventh pin, the eighth pin, the ninth pin, the tenth pin, the eleventh pin and the twelfth pin of the fifth nixie tube DS5 are respectively connected to the thirteenth pin, the twelfth pin, the sixteenth pin, the eleventh pin, the fifteenth pin, the second pin, the tenth pin, the third pin, the fourth pin, the fourteenth pin, the ninth pin and the fifth pin of the third digital control chip U3.

Referring to fig. 9, the third digital control chip U3 can correspondingly control the values displayed by the second digital tube DS2, the third digital tube DS3, the fourth digital tube DS4 and the fifth digital tube DS 5.

Referring to fig. 10, the dosing machine further comprises a second regulation control chip U2 with model GF90F320 for processing parameter regulation of the four peristaltic pumps 2, a second pin of the second digital control chip U2 is connected with a nineteenth pin of the second regulation control chip U2, and a third pin of the second regulation control chip U2 is connected with a seventeenth pin of the second regulation control chip U2; the seventh pin of the third digital control chip U3 is connected with the fifteenth pin connected with the second adjusting control chip U2, and the eighth pin of the third digital control chip U3 is electrically connected with the fourteenth pin of the second adjusting control chip U2. The second regulation control chip U2 is used to process the received signal and transmit it to the second digital control chip U2 and the third digital control chip U3 respectively, so as to control the values displayed by the five nixie tubes.

Referring to fig. 10, a first pin of the second regulation control chip U2 is electrically connected to a first regulation switch S1, one end of the first regulation switch S1 is grounded, a second pin of the second regulation control chip U2 is electrically connected to a second regulation switch S2, one end of the second regulation switch S2 is grounded, a third pin of the second regulation control chip U2 is electrically connected to a third regulation switch S3, one end of the third regulation switch S3 is grounded, a fourth pin of the second regulation control chip U2 is electrically connected to a fourth regulation switch S4, one end of the fourth regulation switch S4 is grounded, a fifth pin of the second regulation control chip U2 is electrically connected to a fifth regulation switch S5, one end of the fifth regulation switch S5 is grounded, a sixth pin of the second regulation control chip U2 is electrically connected to a sixth regulation switch S6, one end of the sixth regulation switch S6 is grounded, a seventh regulation switch S7 is electrically connected to a seventh regulation switch S2, one end of the seventh adjusting switch S7 is grounded, the ninth pin of the second adjusting control chip U2 is electrically connected with the eighth adjusting switch S8, and one end of the eighth adjusting switch S8 is grounded. The eighth pin of the second regulation control chip U2 is connected with a 5V power supply, and the tenth pin of the second regulation control chip U2 is grounded.

Referring to fig. 10, when the rotation speed of the peristaltic pump 2 needs to be adjusted, the first adjustment switch S1 is pressed to enter an adjustment interface, the third adjustment switch S3 and the fourth adjustment switch S4 are respectively and correspondingly increased by one and decreased by one, and the second adjustment switch S2 is used for determining an adjusted value so as to record the adjusted value into the second adjustment control chip U2. For example, when adjusting the parameters of the second peristaltic pump, first press the first adjustment switch S1 to enter an adjustment page, then press the fourth adjustment switch S4 to adjust the positioning to the second peristaltic pump, press the second adjustment switch S2 to enter an adjustment interface of the second peristaltic pump, and then add or subtract the parameters of the second peristaltic pump through the third adjustment switch S3 and the fourth adjustment switch S4, and after the adjustment is completed, press the second adjustment switch S2 for three seconds, and then upload the set parameters to the second adjustment control chip U2.

Referring to fig. 10, the fifth adjustment switch S5, the sixth adjustment switch S6, the seventh adjustment switch S7, and the eighth adjustment switch S8 are the cleaning switches of the first peristaltic pump, the second peristaltic pump, the third peristaltic pump, and the fourth peristaltic pump, respectively, and the corresponding peristaltic pump 2 can be cleaned by pressing the corresponding switches.

Referring to fig. 10, the second regulation control chip U2 is connected with a sixteenth panel terminal P16, and a sixteenth panel terminal P16 is connected with the panel for displaying the code of the peristaltic pump 2.

Referring to fig. 10, the twelfth pin of the second regulation control chip U2 is electrically connected to the second pin of the sixteenth panel terminal P16, the eleventh pin of the second regulation control chip U2 is electrically connected to the third pin of the sixteenth panel terminal P16, the fourth pin of the sixteenth panel terminal P16 is connected to the 5V power supply, and the first pin of the sixteenth panel terminal P16 is grounded.

Referring to fig. 10, a sixteenth pin of the second regulation control chip U2 is connected to an NPN-type fourteenth transistor Q14 through a seventy-seventh resistor R77, a seventy-eighth resistor R78 is connected between a base and an emitter of the fourteenth transistor Q14, an emitter of the fourteenth transistor Q14 is grounded, and a collector of the fourteenth transistor Q14 is connected to a buzzer LS 1.

The implementation principle of the vertical quantifying machine in the embodiment of the application is as follows: through the beverage of presetting several tastes in fifth chip U5, press ninth keypad P9, start the peristaltic pump 2 of presetting quantity simultaneously, the house steward department is taken out to the drink raw materials of peristaltic pump 2 in with the charging chute, and simultaneously, water pump and solenoid valve synergism, in order to take out the water of predetermineeing the water yield in the house steward, drink raw materials and water mix simultaneously at the in-process that the house steward flows, so that the beverage that flows out from the discharging chute is the beverage of allotment and mixed completion, the user can directly drink the beverage that flows from the discharge gate, and is convenient and fast, need not to take out a plurality of single raw materials and put into the beverage bottle in stir the rear and can drink, and the convenience of operation is improved.

When the ratio of beverage needs to be adjusted, the adjusting switch can be adjusted to adjust the rotating speed of the peristaltic pump 2, and the discharge amount of the peristaltic pump 2 is further adjusted, so that the quantifying machine has higher applicability.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by hardware instructions of a computer program, which can be stored in a non-volatile computer-readable storage medium, and when executed, can include the processes of the embodiments of the methods described above. Any reference to memory, storage, database, or other medium used in the embodiments provided herein may include non-volatile and/or volatile memory, among others. Non-volatile memory can include read-only memory (ROM), Programmable ROM (PROM), Electrically Programmable ROM (EPROM), Electrically Erasable Programmable ROM (EEPROM), or flash memory. Volatile memory can include Random Access Memory (RAM) or external cache memory. By way of illustration and not limitation, RAM is available in a variety of forms such as Static RAM (SRAM), Dynamic RAM (DRAM), Synchronous DRAM (SDRAM), Double Data Rate SDRAM (DDRSDRAM), Enhanced SDRAM (ESDRAM), Synchronous Link DRAM (SLDRAM), Rambus Direct RAM (RDRAM), direct bus dynamic RAM (DRDRAM), and memory bus dynamic RAM (RDRAM).

It will be apparent to those skilled in the art that, for convenience and brevity of description, only the above-mentioned division of the functional units and modules is illustrated, and in practical applications, the above-mentioned function distribution may be performed by different functional units and modules according to needs, that is, the internal structure of the apparatus is divided into different functional units or modules to perform all or part of the above-mentioned functions.

The above-mentioned embodiments are only used for illustrating the technical solutions of the present invention, and not for limiting the same; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not substantially depart from the spirit and scope of the embodiments of the present invention, and are intended to be included within the scope of the present invention.

Claims

1. The application relates to a vertical quantifying machine, including the organism and install a plurality of peristaltic pumps in the organism inside, be provided with the identical blow-off groove of quantity and peristaltic pump quantity on the organism, every blow-off groove corresponds and a peristaltic pump intercommunication, is provided with the discharging pipe on the organism, and the quantifying machine still includes MCU module, peristaltic pump control module, regulating module, ejection of compact switch module, water supply module, power module.

2. Through setting up a plurality of peristaltic pump in order to correspond the blowing groove, in order to take out the house steward with the raw materials in the blowing groove under the control of ejection of compact switch module, the raw materials of multiple taste mix at the in-process that the house steward flows, and simultaneously, when the peristaltic pump starts, the water supply module starts, simultaneously to pouring into water in the house steward, drink raw materials mixes the limit flow direction discharging pipe below the promotion of water, and simultaneously, water still has the effect of adjusting allotment drink concentration, so that the beverage that flows from the discharging pipe accords with user's demand more.