CN211338784U

CN211338784U - Distribution control device and distribution equipment

Info

Publication number: CN211338784U
Application number: CN201921441220.2U
Authority: CN
Inventors: 刘育衡
Original assignee: Pomegranate Innovation Co ltd
Current assignee: Pomegranate Innovation Co ltd
Priority date: 2018-09-07
Filing date: 2019-08-30
Publication date: 2020-08-25
Anticipated expiration: 2029-08-30
Also published as: CN110885056B; TWI707653B; WO2020047845A1; TW202025956A; CN110885056A

Abstract

The utility model relates to a distribution control device and distribution equipment, including pressing the response subassembly and with pressing the logic control circuit that the response subassembly is connected, logic control circuit is used for connecting the distributor, presses the response subassembly and is used for dismantling the fixed container that matches to move when following the container and pushing down, presses the response subassembly and is used for detecting according to the container and obtains pressing the information when pushing down, and will press the information transmission to logic control circuit; the logic control circuit is used for receiving the pressing information and sending a feeding control instruction to the distribution device according to the pressing information and the preset corresponding relation, and the feeding control instruction is used for controlling the distribution device to convey materials; and generating a feeding stopping control instruction to the distribution device after detecting that the distribution device finishes feeding operation, wherein the feeding stopping control instruction is used for controlling the distribution device to stop conveying materials. The step of manual selection can be omitted, the distribution device can be controlled to automatically execute distribution actions, the manual operation time is greatly reduced, and the operation efficiency is improved.

Description

Distribution control device and distribution equipment

Technical Field

The utility model relates to a distribution technical field especially relates to a distribution control device and dispensing equipment.

Background

Most restaurants, cafeterias, etc. on the market today are applied to dispensing apparatus for selling drinks, desserts, etc.

However, in the dispensing instruments and equipment adopted in the business places on the market, the staff need to manually select a dispenser capacity button which is needed individually on the dispensing instruments and equipment according to the types of the beverages ordered by the customers and the capacity (large, medium and small) cups each time, so that the operation time of the staff is increased, and the operation efficiency is low.

SUMMERY OF THE UTILITY MODEL

In view of the above, it is necessary to provide an allocation control device and an allocation apparatus with high operation efficiency.

A distribution control device comprises a pressure-action sensing assembly and a logic control circuit, wherein the pressure-action sensing assembly is connected with the logic control circuit, the logic control circuit is used for connecting a distribution device, the pressure-action sensing assembly is used for detachably fixing a matched container and moves along with the container when being pressed downwards,

the pressure-action sensing assembly is used for detecting and obtaining pressure-action information according to the pressing of the container and sending the pressure-action information to the logic control circuit;

the logic control circuit is used for receiving the pressure information and sending a feeding control instruction to the distribution device according to the pressure information and a preset corresponding relation, the feeding control instruction is used for controlling the distribution device to convey materials, and the preset corresponding relation is the corresponding relation between the pressure information and the feeding control instruction; and generating a feeding stopping control instruction to the distribution device after detecting that the distribution device finishes feeding operation, wherein the feeding stopping control instruction is used for controlling the distribution device to stop conveying materials.

A dispensing apparatus comprising a dispensing device and said dispensing control device, said dispensing control device being connected to said dispensing device,

the distribution device is used for receiving the feeding control instruction, extracting the materials according to the feeding control instruction and transmitting the materials.

In the distribution control device and the distribution equipment, the pressure-action sensing assembly is used for detecting and obtaining pressure-action information according to the pressing of the container and sending the pressure-action information to the logic control circuit; the logic control circuit is used for receiving the pressure information and sending a feeding control instruction to the distribution device according to the pressure information and a preset corresponding relation, the feeding control instruction is used for controlling the distribution device to convey materials, and the preset corresponding relation is the corresponding relation between the pressure information and the feeding control instruction; and generating a feeding stopping control instruction to the distribution device after detecting that the distribution device finishes feeding operation, wherein the feeding stopping control instruction is used for controlling the distribution device to stop conveying materials. After the corresponding relation between the pressing information and the control instruction is preset, the steps of manually selecting individual material types and distributing the capacity and quantity of the materials each time according to the distribution requirements of different material types can be omitted, the distribution control device can control the distribution device to automatically execute distribution actions, the manual operation time is greatly reduced, and the operation efficiency is improved.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

FIG. 1 is a block diagram of a distribution control apparatus according to an embodiment;

FIG. 2 is a schematic diagram of an embodiment of a pressure responsive element;

FIG. 3 is a schematic view of a container body according to an embodiment;

FIG. 4 is a schematic view of a container engaging a pressure responsive assembly to follow the container pressure movement in one embodiment;

FIG. 5 is a control diagram illustrating an embodiment of a pressure responsive element configured to execute a dispense command when the pressure responsive element is pressed;

FIG. 6 is a control diagram illustrating the completion of an instruction distribution after the pressure sensing assembly is pressed according to an embodiment;

FIG. 7 is a schematic diagram of an embodiment of a pressure responsive element;

FIG. 8 is a schematic diagram of the operation of a pressure responsive element according to another embodiment;

FIG. 9 is a schematic diagram of the operation of a pressure responsive element according to yet another embodiment;

FIG. 10 is a schematic diagram of the operation of a pressure responsive element according to yet another embodiment;

FIG. 11 is a block diagram of the configuration of a distribution apparatus in one embodiment;

FIG. 12 is a block diagram showing the construction of a distribution apparatus in another embodiment;

FIG. 13 is a block diagram showing the structure of a distribution apparatus in still another embodiment;

FIG. 14 is a block diagram showing the construction of a distribution apparatus in still another embodiment;

FIG. 15 is a schematic diagram of an upper body of the material conveying apparatus in one embodiment;

FIG. 16 is a schematic view of the lower body of the material delivery apparatus in one embodiment;

FIG. 17 is a schematic diagram of a dispensing apparatus according to an embodiment.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

In one embodiment, as shown in fig. 1, a dispensing control device includes a pressure-sensitive component 110 and a logic control circuit 120, wherein the pressure-sensitive component 110 is connected to the logic control circuit 120, the logic control circuit 120 is configured to be connected to a dispensing device, the pressure-sensitive component 110 is configured to detachably fix a matched container and move along with the container when being pressed down, and the pressure-sensitive component 110 is configured to obtain pressure information according to detection of the container when being pressed down and send the pressure information to the logic control circuit 120; the logic control circuit 120 is configured to receive the pressing information, and send a feeding control instruction to the distribution device according to the pressing information and a preset corresponding relationship, where the feeding control instruction is used to control the distribution device to transmit a material, and the preset corresponding relationship is a corresponding relationship between the pressing information and the feeding control instruction; and generating a feeding stopping control instruction to the distribution device after detecting that the distribution device finishes feeding operation, wherein the feeding stopping control instruction is used for controlling the distribution device to stop conveying materials.

Specifically, the logic control circuit 120 is a logic control circuit, the pressing information detected by the pressing sensing component is used to control the dispensing device, the corresponding relationship between the pressing information and the control command is preset in the logic control circuit 120, the pressing information may include a plurality of types without limitation, and may be set according to actual requirements, such as dispensing capacity, and the preset corresponding relationship is material type selection and dispensing capacity corresponding to the pressing information The method is characterized in that the method is used for dispensing the materials such as beverages or other liquids/semi-liquids/solids, and is particularly suitable for occasions (such as commercial environments with multiple streams, such as restaurants, fast food restaurants and the like) needing quick and frequent use, the steps of manually selecting individual material types and dispensing the capacity and quantity of the materials each time required by the demands of dispensing different material types can be omitted after the first presetting is completed, the dispensing control device can control the dispensing device to automatically perform the dispensing action, and after the dispensing device performs the dispensing action, a user can conveniently take away the container, so that the manual operation time is greatly reduced, and the operation efficiency is improved.

In one embodiment, the pressing information includes a pressing position and/or a pressing amplitude, the logic control circuit 120 is configured to receive the pressing position and/or the pressing amplitude, and send a feeding control command to the corresponding dispensing device according to the pressing position and/or the pressing amplitude and the preset corresponding relationship, where the feeding control command is used to control the corresponding dispensing device to deliver the material.

Specifically, the pressing position refers to, for example, arranging pressing mechanisms 111 at different positions of the pressing sensing assembly 110, as shown in fig. 2, each position is preset to correspond to a feeding control instruction, for example, two pressing mechanisms a and B are arranged on the pressing sensing assembly 110, it is understood that the number of the pressing mechanisms is not limited to two, and may include any number, the pressing mechanism a correspondingly dispenses 350mL of water, and the pressing mechanism B correspondingly dispenses 5 ice cubes; the pressing amplitude refers to the pressing force of each pressing mechanism, and each amplitude is preset to correspond to a feeding control instruction, if the pressing mechanism A is pressed to a first gear, 350mL of water is distributed correspondingly, and when the pressing mechanism A is pressed to a second gear, 400mL of water is distributed correspondingly; or the pressing mechanism A can be set to correspondingly distribute 350mL of water, the pressing mechanism B can be set to correspondingly distribute 400mL of water as another control mode, and the like.

In one embodiment, a groove is formed on the inner surface of the pressure-sensitive component 110, and a protrusion is formed on the outer surface of the container at a corresponding position; or a bulge is arranged on the inner surface of the pressure induction component 110, and a groove or a bulge is arranged on the outer surface of the container at a corresponding position; or the inner surface of the pressure induction component 110 is provided with a groove and a bulge, and the corresponding position of the outer surface of the container is provided with a bulge and a groove or a bulge.

Specifically, as shown in fig. 3, the convex position may be disposed at the bottom of the container or at the side of the container, the concave position or the convex position corresponding to the bottom of the container of the pressure-sensitive component 110 is disposed at the bottom of the container for matching and allowing self-reaction to identify the type, the volume and the amount of the required material, and so on, the convex position corresponding to the bottom of the container of the pressure-sensitive component 110 is disposed at the bottom of the container for matching and allowing self-reaction to identify the type, the volume and the amount of the required material, the convex position corresponding to the side of the container of the pressure-sensitive component 110 is disposed at the side of the container for matching and allowing self-reaction to identify the type, the volume and the amount of the required material, and the convex position corresponding to the side of the container of the pressure-sensitive component 110 is disposed at the side of the container for matching and allowing self-reaction to identify the type, the amount of the required, Concave or convex bits set by the allocated capacity and amount. A schematic view of the container body and the pressure responsive assembly 110 in one embodiment.

It is to be understood that the position, shape and amount of the concave-convex portion of the container and the position, shape and amount of the concave-convex portion of the sensing element, which are exemplified in the above description, are not limited to the examples given in the description, and the configuration position may be concave or convex, the amount of the concave-convex portion relative to the mating portion, and the position of the concave-convex portion in the container and the sensing element may be defined according to the requirements of the practical design application environment, and the shape of the concave-convex portion is not limited.

Further, taking the example of disposing the protrusion on the inner surface of the pressure sensing component 110 and disposing the groove on the outer surface of the container as an example, the user first presets the material type, dispensing capacity, and quantity execution specification required by the container corresponding to the respective different quantities of the protrusion, so that the logic control circuit can execute the preset requirement according to the storage, that is, the preset condition and the subsequent execution requirement according to the preset condition, for example, the container with 2 protrusions is attached to the designated position, the user presets the container to dispense 350mL of water and 5 ice cubes, the user places the container with the pressure sensing component 110 aligned to the protrusion (that is, the corresponding pressure position in the pressure information), triggers the pressure sensing component 110 to generate the pressure information to the logic control circuit 120, and the logic control circuit 120 controls the dispensing device to dispense 350mL of water and 5 ice cubes according to the preset condition. As shown in fig. 4, the protrusion on the bottom of the container presses the pressing mechanism of the pressing sensing assembly 110 (in this case, the button (i.e. pressing mechanism, hereinafter referred to as button) a and the button C are pressed, but the button B side is not pressed), at this time, as shown in fig. 5, the logic control circuit 120 obtains the signals of the buttons a and C of the pressing sensing assembly 110, and does not have the signal of B, and presses the preset identification of the user, and it is required to dispense 350mL of water and 5 ice cubes, as shown in fig. 6, after detecting that 350mL of water and 5 ice cubes are dispensed, the logic control circuit stops the dispensing operation, and then the user can freely repeat the placement of the material type and the dispensing of the preset individual container to trigger the automatic execution of the preset command. In other embodiments, the protrusion on the side of the container pushes the opposite pressure-sensitive component 110 (in this case, button a and button C are pushed, and button B is not pushed); in other embodiments, the bottom of the container has a recess that receives the opposing sensing element (in this case, button A and button C are received by the recess space and not depressed, and instead button B is not received by the recess space and is depressed); in other embodiments, the side of the container has a recess that receives the opposing sensing element (in this case, button A and button C are received by the recess space and not pushed, and button B is not received by the recess space and pushed instead). The dispensing material outlets exemplified in the description of the present application are not limited to or specified amounts, and the pressing, pushing and pushing portions of the sensing assembly are not limited to the examples in this description and may be determined according to individual application requirements.

In one embodiment, as shown in fig. 7, the pressure-actuated sensing assembly 110 includes a tray, a pressure-actuated mechanism, a magnetic induction switch integrated circuit 112 and a magnet 113, the pressure-actuated mechanism is disposed on the tray, the magnet 113 is disposed on the pressure-actuated mechanism and is opposite to the magnetic induction switch integrated circuit 112, the magnetic induction switch integrated circuit 112 is connected to the logic control circuit 120, the pressure-actuated mechanism is configured to move along with the container pressure, and the magnetic induction switch integrated circuit 112 is configured to generate pressure-actuated information according to the magnetic force variation sensed when the magnet 113 is pressed and transmit the pressure-actuated information to the logic control circuit 120.

Specifically, the relative arrangement can be relatively vertical or relatively horizontal, the magnet is arranged on the pressing mechanism, when the pressing mechanism is pressed, pressed or pushed to be close to the magnetic induction switch integrated circuit electronic element, the magnetic force of the magnet is enhanced until the magnetic induction integrated circuit element senses enough magnetic force, the output of the magnetic induction integrated circuit element can generate voltage change and convert the voltage change into pressing information, the logic control circuit is enabled to distinguish the state change, and therefore the distribution device is controlled to execute corresponding operation according to the received pressing information.

In one embodiment, as shown in fig. 8, the pressure-actuated sensing component 110 includes a tray, a pressure-actuated mechanism, a current sensing ic 114 and a conductive component 115, the pressure-actuated mechanism is disposed on the tray, the conductive component 115 is disposed on the pressure-actuated mechanism and is opposite to the current sensing ic 114, the current sensing ic 114 is connected to the logic control circuit 120, the pressure-actuated mechanism is configured to move along with the pressure of the container, and the current sensing ic 114 is configured to generate pressure-actuated information according to the current variation sensed when the conductive component 115 is pressed and transmit the pressure-actuated information to the logic control circuit 120.

Specifically, the conductive assembly is arranged on the pressing mechanism, when the pressing mechanism is pressed, pressed or pushed to contact the current sensing integrated circuit to generate current conduction, the current sensing integrated circuit can be converted into pressing information due to the change of the current, and the logic control circuit is enabled to distinguish the change of the state, so that the distribution device is controlled to execute corresponding operation according to the received pressing information.

In one embodiment, as shown in fig. 9, the pressure-actuated sensing component 110 includes a tray, a pressure-actuated mechanism, a pressure-actuated component and a piezoelectric sensing integrated circuit 116, the pressure-actuated mechanism is disposed on the tray, the pressure-actuated component is disposed on the pressure-actuated mechanism and opposite to the piezoelectric sensing integrated circuit 116, the pressure-actuated component is connected to the logic control circuit 120, the pressure-actuated mechanism moves along with the container pressure, and the piezoelectric sensing integrated circuit 116 is configured to generate corresponding pressure-actuated information according to the voltage or current change sensed when the pressure-actuated component is pressed and send the corresponding pressure-actuated information to the logic control circuit 120.

Specifically, the pressing component is disposed on the pressing mechanism, and when the pressing mechanism is pressed, pressed or pushed to press the piezoelectric sensing integrated circuit to apply pressure, the piezoelectric sensing integrated circuit generates a certain output (voltage/current) change due to the applied pressure and converts the output into pressing information, so that the logic control circuit can distinguish the state change, and the distribution device is controlled to execute corresponding operations according to the received pressing information.

In one embodiment, as shown in fig. 10, the pressure-actuated sensing assembly 110 includes a tray, a pressure-actuated mechanism, a pressure-actuated assembly 117 and a circuit switch 118, the pressure-actuated mechanism is disposed on the tray, the pressure-actuated assembly 117 is disposed on the pressure-actuated mechanism and opposite to the circuit switch 118, the circuit switch 118 is connected to a logic control circuit 120, the pressure-actuated mechanism moves along with the container pressure, and the circuit switch 118 is configured to generate corresponding pressure-actuated information according to the state change of the circuit switch when the pressure-actuated assembly 117 is pressed and transmit the corresponding pressure-actuated information to the logic control circuit 120.

Specifically, the pressing component is arranged on the pressing mechanism, when the pressing mechanism is pressed, pressed or pushed to the circuit switch, the circuit switch can generate state change due to the applied pressing, the state change of the switch is converted into pressing information, the logic control circuit is made to distinguish the state change, and therefore the distribution device is controlled to execute corresponding operation according to the received pressing information.

In one embodiment, the pressure-activated sensing device 110 may be a tray, a pressure-activated mechanism disposed on the tray, a conductive device disposed on the pressure-activated mechanism and disposed opposite to the general Circuit, the general Circuit is connected to the logic control Circuit 120, and the conductive device is disposed on the pressure-activated mechanism, so that when the pressure-activated mechanism is pressed, activated or pushed to contact the general Circuit for conduction (Closed Circuit), the logic control Circuit can distinguish the state change, thereby controlling the dispensing device to perform the corresponding operation according to the received pressure-activated information.

The above-described examples of the electronic induction system are not limited to the examples, and particularly, the electronic induction system is many and can be implemented by other electronic induction systems. The sensing elements in the present application are only exemplified by simple on/off logic, and the sensing manner can be defined as pressing, and pushing amplitude of the sensing portion to perform different units to identify the required individually allocated command execution actions.

The distribution control device described above, considering the current global economic situation, also reduces the operating costs of multiple merchants (restaurants, cafes, bars, etc.) as much as possible, thus bringing the following economic advantages: greatly reducing waste of time and materials due to human errors caused by selection of material types, allocated capacity and amount; reducing the ratio of time required (especially in the case of salary) by employees, attendants, etc. in preparing for the dispensing of materials such as beverages, can allow more time to be scheduled for other work tasks, or can thus reduce the cost of the employees required; in contrast to conventional dispensing apparatus and machines, it allows a single container to be positioned with a plurality of dispensing openings in a centralized manner without requiring the dispensing openings to occupy area for individual material types, thereby eliminating the need for multiple dispensing outlet positions.

In one embodiment, as shown in fig. 11, a dispensing apparatus comprises a dispensing device 300 and the dispensing control device 100, the dispensing control device 100 is connected to the dispensing device 300, and the dispensing device 300 is used for receiving a feeding control command, extracting and conveying materials according to the feeding control command.

Specifically, the distribution device 300 is configured to extract the corresponding material according to the feeding control instruction sent by the distribution control device 100 and transmit the extracted material to the container, and stop extracting the corresponding material according to the feeding stop control instruction sent by the distribution control device 100 and transmit the extracted material to the container, so as to complete the material distribution process through cooperation of the two.

In one embodiment, as shown in fig. 12, the dispensing device 300 includes a material storage container 310 and a feeding control device 320, the material storage container 310 is connected to the feeding control device 320, the feeding control device 320 is communicatively connected to the dispensing control device 100, the feeding control device 320 is configured to receive a feeding control command, extract a corresponding amount of material from the material storage container 310 according to the feeding control command and transmit the material, and receive a feeding stop control command, and stop extracting the material according to the feeding stop control command.

Specifically, the material storage container 310 is a liquid, semi-liquid or solid storage container, and one dispensing device may include a plurality of material storage containers 310, which may be combined and matched according to actual needs, for example, a semi-liquid and a solid storage container are included at the same time, and the specific types of the materials are not limited, and may be liquids such as water and beverages, semi-liquids such as ice cream, ice slush beverages and soft ice cream, or solids such as ice cubes and sugar particles.

In one embodiment, as shown in fig. 13 and 14, the feeding control device 320 comprises a pump 322 and/or a quantity distribution device 324, when the feeding control device 320 comprises the pump 322 and the quantity distribution device 324, the material storage container 310 comprises a liquid/semi-liquid material storage container 312 and a solid material storage container 314, the distribution device further comprises a material conveying device 330, the liquid/semi-liquid material storage container 312 is connected with the pump 322 through the material conveying device 330, the solid material storage container 314 is connected with the quantity distribution device 324, and the pump 322 and the quantity distribution device 324 are connected with the distribution control device; when the feeding control device 320 is a pump 322, the material storage container 310 is a liquid/semi-liquid material storage container 312, the dispensing device further comprises a material conveying device 330, the liquid/semi-liquid material storage container 312 is connected with the pump 322 through the material conveying device 330, and the pump 322 is connected with the dispensing control device; when the feed control device 320 is a quantity dispensing device 324, the material storage container 310 is a solid material storage container 314, and the solid material storage container 314 is connected to the dispensing control device through the quantity dispensing device 324.

Specifically, when the material is in the liquid or semi-liquid type, the corresponding material storage container 310 is a liquid/semi-liquid material storage container 312, the corresponding feed control device 320 is a pump 322, when the material is in the solid type, the corresponding material storage container 310 is a solid material storage container 314, and the corresponding feed control device 320 is a quantity distribution device 324. When the feeding control device 320 includes the pump 322, it further includes the material conveying device 330, and the pump 322 controls the material conveying device 330 to extract and convey the material from the material storage container 310.

In one embodiment, as shown in fig. 15 and 16, the material conveying device 330 includes an upper body 10 and a lower body 20, the upper body 10 includes a fixing member 12 and a lifting member 11, the fixing member 12 is fixedly disposed on the inner bottom surface of the upper body 10, the lifting member 11 is disposed inside the fixing member 12 and can move up and down, a flow hole 16 is disposed on the side wall of the lifting member 11, a perfusion flow channel 15 is disposed in the middle of the lifting member 11, and the perfusion flow channel 15 passes through the bottom of the upper body 10; the lower body 20 comprises a cover plug 21 and a rigid column 22, the cover plug 21 is fixedly connected with the rigid column 22, a channel is arranged in the rigid column 22, and the outer side wall of the cover plug 21 can be clamped with the inner side wall of the lifting piece 11.

Further, the upper body 10 includes a fixing member 12 and a lifting member 11, the fixing member 12 is fixedly disposed on the inner bottom surface of the upper body 10, the lifting member 11 is disposed inside the fixing member 12 and can move up and down, in this embodiment, the fixing member 12 and the lifting member 11 are both circular, but may be disposed in other shapes; the side wall of the lifting member 11 is provided with a flow hole 16 for performing pouring, and the middle of the lifting member 11 is provided with a pouring flow passage 15, and the pouring flow passage 15 passes through the bottom of the upper body 10.

The lower body 20 comprises a cover plug 21, a rigid column 22, an outer ring extension tube 24, an inner ring extension tube 26, an inner channel 28 and a connecting rubber tube 29, wherein the outer ring extension tube 24 comprises a top plate 24a, a bottom plate 24b and a side wall 24c for connecting the top plate and the bottom plate, a spring 25 is arranged between the top plate 24a and the bottom plate 24b, the rigid column 22 is arranged on the top plate 24a, the rigid column 22 is made of firm materials and can play a supporting role, and if the rigid column 22 is made of stainless steel materials, the stainless steel materials are not. The rigid cylinder 22 has a passage inside, the inner ring telescopic tube 26 is arranged inside the outer ring telescopic tube 24 and communicated with the rigid cylinder 22, and the inner ring telescopic tube 26 is made of elastic material, such as rubber material, which has low cost, good elasticity and long service life. The spring 25 is located outside the inner ring telescopic tube 26, a second leakage-proof ring 212 is arranged at a joint of the rigid cylinder 22 and the top plate 24a, a support base 27 is arranged on the bottom plate 24b, a support column 23 is arranged on the support base 27, the support column 23 penetrates through the inner ring telescopic tube 26 and extends into the rigid cylinder 22, a cover plug 21 is fixedly arranged at the top of the support column 23, the cover plug 21 is fixedly connected with the top of the rigid cylinder 22, a first leakage-proof ring 211 is arranged at a joint of the cover plug 21 and the rigid cylinder 22, the rigid cylinder 22 is located inside the lifting piece 11, the outer side wall of the cover plug 21 and the inner side wall of the top of the lifting piece 11 are clamped through the matching of the clamping position 14 and the convex position 210, in this embodiment, the clamping position 14 is arranged on the inner side wall of the top of the lifting piece 11. The internal channel 28 is fixedly connected with the bottom plate 24b and communicated with the rigid column 22, and the connecting rubber tube 29 is communicated with the bottom of the internal channel 28.

Specifically, when the material conveying device 330 is used, the material conveying device is used in cooperation with the feeding control device 320, the upper body is pressed downwards, the fixing piece moves downwards along with the upper body, the rigid cylinder drives the lifting piece to move upwards through the cover plug, the circulation hole is exposed outside, and at the moment, liquid/semi-liquid can flow from the lower body to the upper body and is discharged from the circulation hole, so that the filling work is realized. The material conveying device 330 can be applied to the filling of various water, beverages or other liquid/semi-liquid as well as ice cream machines and ice slush, and has the advantages of high filling speed, high efficiency and high safety performance, for example, the problem that the splashing of high-temperature liquid during conveying and the subsequent scalding of users can be reduced; meanwhile, the mode of pouring from the lower net reduces the spilling condition generated during pouring and greatly reduces the foam generated during pouring of the carbonic acid liquid, thereby avoiding the action of pouring the liquid; the upper body in the design is filled from a liquid supply source by matching with a simple natural water flow principle; the application of the design can break through the pouring mode of various liquids such as traditional beverages and drinks, semi-liquid state materials and the like from top to bottom, and the operation is simple.

In one embodiment, as shown in fig. 14, when the feeding control device 320 is a pump 322, the dispensing device 200 further includes a temperature control device 340, the material conveying device 330 is connected to the temperature control device 340, and the pump 322 receives a feeding control command, extracts the material from the material storage container according to the feeding control command, and conveys the material, including: the pump 322 receives the feeding control instruction, and controls the material conveying device 330 to extract the material from the liquid/semi-liquid material storage container 312 according to the feeding control instruction and convey the material to the temperature control device; the temperature control device 340 controls the temperature of the received material to a preset temperature and then delivers it.

Specifically, when the material is liquid or semi-liquid, the temperature control device 340 is used for performing temperature control on the material, and when the distribution equipment comprises the temperature control device 340, correspondingly, the control instruction comprises corresponding temperature control information, the pump 322 receives a feeding control instruction, and controls the material conveying device 330 to extract the material from the liquid/semi-liquid material storage container 312 according to the feeding control instruction and convey the material to the temperature control device 340; the temperature control device 340 controls the temperature of the received material to a preset temperature and then delivers it.

In one embodiment, as shown in fig. 14, the dispensing apparatus further includes a flow detection device 350, the flow detection device 350 is communicatively connected to the dispensing control device 100, the flow detection device 350 is configured to detect the flow rate of the material and send the flow rate to the dispensing control device 100; the distribution control device 100 receives the flow rate, and when detecting that the flow rate is inconsistent with the preset flow rate, sends a flow rate control instruction to the pump 322 until the flow rate fed back by the flow rate detection device 350 is consistent with the preset flow rate; the pump 322 is used to control the dispense flow rate according to the received flow control command.

Specifically, the specific type of the flow detection device 350 is not limited, and the flow detection device 350 is adjusted according to the type of the material, and the corresponding flow detection device 350 feeds back the flow of the material to the logic control circuit to ensure that the dispensed capacity is correct. The applicable scope of the present application includes but is not limited to: various liquid dispensing applications (e.g., drinking water, beverage volume), various semi-liquid dispensing applications (e.g., ice-sand drinks, soft ice cream volume), and various solids dispensing applications (e.g., ice cube, sugar mass).

In practical application, as shown in fig. 17, taking an example that a liquid/semi-liquid material storage container and a solid material storage container are included at the same time, a specific flow is as follows: 1. placing the container on a designated location of the dispensing apparatus; 2. the convex position of the bottom of the container presses the opposite pressing mechanism (the button a and the button c are pressed, while the button b side is not pressed), and at the moment, relevant signals are transmitted to the logic control circuit; furthermore, the container can be a special container or a common container, and when the container is a common container, a device matched with the pressing mechanism can be detachably fixed at the corresponding position of the common container so as to press the corresponding pressing mechanism; 3. the logic control circuit is controlled according to the state signal of the sensing component pressed at the bottom of the container, the motor (corresponding to the feeding control device 220) of the water pump 222 is started to distribute water, and an instruction is transmitted to ensure that the ice distribution meter (corresponding to the feeding control device 220) only distributes 5 ice cubes; 4. when the motor of the water pump 222 is appointed to be started, the corresponding flow meter feeds back water flow to the logic control circuit, and the logic control circuit stops the motor of the water pump 222 and water distribution until the capacity of 350mL is reached; 5. therefore, when 5 ice cubes with a volume of 350mL are dispensed/dispensed into the container, the operation command is completed, the dispensing device automatically stops after completing a set of commands, and the user can directly take the container which is dispensed/dispensed.

The distribution control device and the distribution equipment are an automatic capacity and quantity identification distribution structure principle which promotes efficiency and is innovative, (can be applied to various water, beverages or other liquid/semi-liquid/solid and other materials which can be distributed and distributed), and are particularly suitable for occasions needing quick and frequent use (such as a restaurant, a fast food restaurant and other multi-people commercial environments). After the first presetting is finished, the steps of manually selecting individual material types, the capacity and the quantity of the distribution and distribution materials by hands each time according to different material types and distribution requirements, such as a soda machine adopted in a restaurant on the market, a waiter of the restaurant needs to press the beverage type ordered by a client each time, and a capacity (large, medium and small) cup manually selects an individual required distributor capacity button on the soda machine, but the distribution informing device and the distribution equipment can omit the step that the waiter needs to manually press the individual distribution capacity button each time, so that the operation time of the waiter can be greatly reduced relatively, and the operation efficiency is improved.

The technical features of the above embodiments can be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the above embodiments are not described, but should be considered as the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the utility model. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims

1. A distribution control device is characterized by comprising a pressure-action sensing assembly and a logic control circuit, wherein the pressure-action sensing assembly is connected with the logic control circuit, the logic control circuit is used for connecting a distribution device, the pressure-action sensing assembly is used for detachably fixing a matched container and moves along with the downward pressing of the container,

2. The distribution control device according to claim 1, wherein the pressing information includes a pressing position and/or a pressing amplitude, the logic control circuit is configured to receive the pressing position and/or the pressing amplitude, and send a feeding control command to the corresponding distribution device according to the pressing position and/or the pressing amplitude and a preset corresponding relationship, and the feeding control command is configured to control the corresponding distribution device to deliver the material.

3. The dispensing control device of claim 1, wherein the pressure-actuated sensing assembly comprises a tray, a pressure-actuated mechanism, a magnetic induction switch integrated circuit and a magnet, the pressure-actuated mechanism is disposed on the tray, the magnet is disposed on the pressure-actuated mechanism and is disposed opposite to the magnetic induction switch integrated circuit, the magnetic induction switch integrated circuit is connected to the logic control circuit, the pressure-actuated mechanism is configured to move along with the container pressure, and the magnetic induction switch integrated circuit is configured to generate pressure-actuated information according to the magnetic force variation sensed when the magnet is pressed and send the pressure-actuated information to the logic control circuit.

4. The dispensing control device according to claim 1, wherein the pressure-actuated sensing assembly includes a tray, a pressure-actuated mechanism, a current-sensing integrated circuit and a conductive assembly, the pressure-actuated mechanism is disposed on the tray, the conductive assembly is disposed on the pressure-actuated mechanism and is disposed opposite to the current-sensing integrated circuit, the current-sensing integrated circuit is connected to the logic control circuit, the pressure-actuated mechanism is configured to move along with the container pressure, and the current-sensing integrated circuit is configured to generate pressure-actuated information according to a current change sensed when the conductive assembly is pressed and transmit the pressure-actuated information to the logic control circuit.

5. The dispensing control device according to claim 1, wherein the pressure-actuated sensing assembly comprises a tray, a pressure-actuated mechanism, a pressure-actuated assembly and a piezoelectric sensing integrated circuit, the pressure-actuated mechanism is disposed on the tray, the pressure-actuated assembly is disposed on the pressure-actuated mechanism and is disposed opposite to the piezoelectric sensing integrated circuit, the pressure-actuated sensing integrated circuit is connected to the logic control circuit, the pressure-actuated mechanism moves along with the pressure of the container, and the piezoelectric sensing integrated circuit is configured to generate corresponding pressure-actuated information according to the voltage or current change sensed by the pressure-actuated assembly when the pressure-actuated assembly is pressed and send the corresponding pressure-actuated information to the logic control circuit.

6. The dispensing control device according to claim 1, wherein the pressure-actuated sensing assembly includes a tray, a pressure-actuated mechanism, a pressure-actuated assembly and a circuit switch, the pressure-actuated mechanism is disposed on the tray, the pressure-actuated assembly is disposed on the pressure-actuated mechanism and is disposed opposite to the circuit switch, the circuit switch is connected to the logic control circuit, the pressure-actuated mechanism moves along with the container pressure actuation, and the circuit switch is configured to generate corresponding pressure-actuated information according to a state change of the circuit switch when the pressure-actuated assembly is pressed and transmit the corresponding pressure-actuated information to the logic control circuit.

7. Dispensing device, characterized in that it comprises a dispensing means and a dispensing control means according to any of claims 1-6, which dispensing control means is connected to the dispensing means,

8. The dispensing apparatus according to claim 7 wherein the dispensing device includes a material storage container and a feed control device, the material storage container being connected to the feed control device, the feed control device being communicatively connected to the dispensing control device,

the feeding control device is used for receiving a feeding control instruction, extracting a corresponding amount of materials from the material storage container according to the feeding control instruction and transmitting the materials; and receiving a feeding stopping control instruction, and stopping extracting the materials according to the feeding stopping control instruction.

9. Dispensing device according to claim 8, characterized in that the feed control means comprise a pump and/or a quantity dispensing means,

when the feeding control device comprises a pump and a quantity distribution device, the material storage container comprises a liquid/semi-liquid material storage container and a solid material storage container, the distribution device further comprises a material conveying device, the liquid/semi-liquid material storage container is connected with the pump through the material conveying device, the solid material storage container is connected with the quantity distribution device, and the pump and the quantity distribution device are connected with the distribution control device;

when the feeding control device is a pump, the material storage container is a liquid/semi-liquid material storage container, the distribution device further comprises a material conveying device, the liquid/semi-liquid material storage container is connected with the pump through the material conveying device, and the pump is connected with the distribution control device;

when the feeding control device is a quantity distribution device, the material storage container is a solid material storage container, and the solid material storage container is connected with the distribution control device through the quantity distribution device.

10. The dispensing apparatus according to claim 9 further comprising a temperature control device when the feed control device is a pump, the material delivery device being connected to the temperature control device,

the pump receives a feeding control instruction, extracts materials from the material storage container according to the feeding control instruction and conveys the materials, and the method comprises the following steps:

the pump receives the feeding control instruction, and controls the material conveying device to extract materials from the liquid/semi-liquid material storage container and convey the materials to the temperature control device according to the feeding control instruction;

the temperature control device controls the temperature of the received material to be at a preset temperature and then transmits the temperature.

11. The dispensing apparatus of claim 10 further comprising a flow sensing device communicatively coupled to the dispensing control device,

the flow detection device is used for detecting the flow of the materials and sending the flow to the distribution control device;

the distribution control device is used for receiving the flow, and sending a flow control instruction to the pump when the flow is detected to be inconsistent with a preset flow until the flow fed back by the flow detection device is consistent with the preset flow;

the pump is used for controlling the distribution flow according to the received flow control command.