TWI707653B - Distribution control device and distribution equipment - Google Patents

Abstract

The invention relates to a distribution control device and a distribution equipment, comprising a pressure sensing component and a logic control circuit, the pressure sensing component is connected to the logic control circuit, the logic control circuit is used to connect the distribution device, and the pressure sensing component is used for detachable fixed matching The container moves when the container is pressed down. The pressure sensing component is used to detect the pressure information when the container is pressed down, and send the pressure information to the logic control circuit; the logic control circuit is used to receive the pressure information, according to the pressure Dynamic information and the preset correspondence relationship send feeding control instructions to the distribution device, the feeding control instructions are used to control the distribution device to deliver materials; and after detecting that the distribution device has completed the feeding operation, it generates a stop feeding operation instruction to the distribution device to stop the feeding control instruction Used to control the distribution device to stop transferring materials. The manual selection step can be omitted, and the distribution device can be controlled to automatically perform the distribution action, which greatly reduces the manual operation time and improves the operating efficiency.

Description

Distribution control device and distribution equipment

The present invention relates to the field of distribution technology, in particular to a distribution control device and distribution equipment.

At present, most restaurants, coffee shops, etc. on the market will be used to distribute equipment to sell drinks, desserts, etc.

However, for the dispensing equipment used in the business premises on the market, the staff needs to manually select the individual required dispenser capacity buttons on the dispensing equipment according to the type of beverage ordered by the customer and the capacity (large, medium and small) cups. The operating time of the staff is low and the operating efficiency is low.

Based on this, it is necessary to provide a distribution control device and distribution equipment with high operational efficiency in response to the above technical problems.

Therefore, in order to achieve the above objective, the present invention provides a distribution control device, which includes a pressure sensing component and a logic control circuit. The pressure sensing component is connected to the logic control circuit. The logic control circuit is used to connect to the distribution device. The component is used to detachably fix the matched container, and follow the container to move when it is pressed down. The pressure sensing component is used to obtain the pressure dynamic data based on the detection when the container is pressed down. And send the pressure information to the logic control circuit; the logic control circuit is used to receive the pressure information, and send a feeding control instruction to the distribution device according to the pressure information and a preset correspondence relationship, the feeding control instruction Used to control the distribution device to deliver materials, wherein the preset correspondence is the correspondence between the pressure information and the feeding control command; and after detecting that the dispensing device has completed the feeding operation, a feeding stop operation instruction is generated to the distribution Device, the stop feeding control instruction is used to control the distribution device to stop feeding materials.

At the same time, the present invention further provides a distribution equipment, including a distribution device and the above-mentioned distribution control device, the distribution control device is connected to the distribution device, the distribution device is used to receive a feeding control instruction, according to the feeding control instruction to extract materials and transfer .

In the above-mentioned distribution control device and distribution equipment, the pressure sensing component is used to detect the pressure motion information when the container is pressed down, and send the pressure motion information to the logic control circuit; the logic control circuit is used to receive the pressure motion information according to the pressure motion information Send a feeding control instruction to the distribution device with a preset correspondence. The feeding control instruction is used to control the dispensing device to deliver materials. The preset correspondence is the correspondence between the pressure information and the feeding control instruction; and when the dispensing device is detected After the feeding operation is completed, an instruction to stop feeding is generated to the distribution device, and the feeding stop control instruction is used to control the distribution device to stop transferring materials. After the corresponding relationship between the pressure information and the control command is preset, it is possible to omit the manual selection of individual material categories, the steps of distributing the capacity and quantity of the materials, and the distribution control. The device can control the distribution device to automatically perform the distribution action, which greatly reduces the manual operation time and improves the operation efficiency.

100‧‧‧Distribution control device

110‧‧‧Pressure Sensing Components

111‧‧‧Compress Motivation to Purchase

112‧‧‧Magnetic induction switch integrated circuit

113‧‧‧Magnet

114‧‧‧Current Sensing Integrated Circuit

115‧‧‧Conductive component

116‧‧‧Piezoelectric induction integrated circuit

117‧‧‧Pressure component

118‧‧‧Circuit switch

120‧‧‧Logic control circuit

300‧‧‧Distribution device

310‧‧‧material storage container

312‧‧‧Liquid/semi-liquid material storage container

314‧‧‧Solid material storage container

320‧‧‧Feeding control device

322‧‧‧Pump

324‧‧‧Quantity Distribution Device

330‧‧‧Material Conveying Device

10‧‧‧Upper body

11‧‧‧Lifting parts

12‧‧‧Fixed parts

14‧‧‧Card slot

15‧‧‧Perfusion channel

16‧‧‧Circulation hole

20‧‧‧Lower Body

21‧‧‧Guest

22‧‧‧Rigid cylinder

23‧‧‧Support column

24‧‧‧Outer ring telescopic tube

24a‧‧‧Top plate

24b‧‧‧Bottom plate

24c‧‧‧ side wall

25‧‧‧Spring

26‧‧‧Inner ring telescopic tube

27‧‧‧Supporting the foundation

28‧‧‧Internal Channel

29‧‧‧Connecting hose

210‧‧‧Protrusion

211‧‧‧The first leakproof ring

212‧‧‧Second anti-leak ring

340‧‧‧Temperature control device

350‧‧‧Flow detection device

In order to more clearly illustrate the embodiments of the present invention or the prior art Technical solutions, the following will briefly introduce the drawings that need to be used in the description of the embodiments or the prior art. Obviously, the drawings in the following description are only some embodiments of the present invention, and are for those of ordinary skill in the art. Under the premise of no creative work, the schemas of other embodiments can also be obtained based on these schemas.

Figure 1 is a schematic diagram of the structure of the distribution control device in an embodiment; Figure 2 is a schematic diagram of the structure of the pressure sensing component in an embodiment; Figure 3 is a schematic diagram of the container body structure in an embodiment; Figure 4 is an embodiment A schematic diagram of a container equipped with a pressure sensing component to follow the pressure movement of the container; Figure 5 is a schematic diagram of the control of the pressure sensing component in an embodiment after being pressed to execute a distribution command; Figure 6 is a pressure sensing component in an embodiment After being pressed, the command distribution is completed; Figure 7 is a schematic diagram of the working principle of the pressure-sensitive component in one embodiment; Figure 8 is a schematic diagram of the working principle of the pressure-sensitive component in another embodiment; Figure 9 is A schematic diagram of the working principle of the pressure sensitive component in another embodiment; Figure 10 is a schematic diagram of the working principle of the pressure sensitive component in another embodiment; Figure 11 is a schematic diagram of the structure of a distribution device in one embodiment; Figure 12 is A schematic diagram of the architecture of a distribution device in another embodiment; FIG. 13 is a schematic diagram of the architecture of a distribution device in another embodiment; Figure 14 is a schematic diagram of the structure of the distribution equipment in another embodiment; Figure 15 is a schematic diagram of the upper body structure of the material conveying device in one embodiment; Figure 16 is a schematic diagram of the lower body structure of the material conveying device in one embodiment; and Figure 17 is a schematic structural diagram of a distribution device in an embodiment.

In order to make the purpose, technical solutions, and advantages of the present application clearer, the following further describes the present application in detail with reference to the drawings and embodiments. It should be understood that the specific embodiments described here are only used to explain the application, and not used to limit the application.

In one embodiment, as shown in Figure 1, a distribution control device includes a pressure sensing component 110 and a logic control circuit 120. The pressure sensing component 110 is connected to the logic control circuit 120, and the logic control circuit 120 is used to connect to the distribution device. , The pressure sensing component 110 is used to detachably fix the matched container and follow the movement when the container is pressed down. The pressure sensing component 110 is used to detect the pressure when the container is pressed down, and send the pressure information to the logic control Circuit 120; the logic control circuit 120 is used to receive pressure information, and send a feeding control instruction to the distribution device according to the pressure information and a preset correspondence relationship. The feeding control instruction is used to control the distribution device to deliver materials. The preset correspondence relationship is pressure The corresponding relationship between the movement information and the feeding control command; and after detecting that the dispensing device completes the feeding operation, a feeding stop operation command is generated to the dispensing device, and the feeding stop control command is used to control the dispensing device to stop feeding materials.

Specifically, the logic control circuit 120 is a logic control circuit, pressing the pressure information detected by the motion sensing component 110 to control the distribution device, and the corresponding relationship between the pressure information and the control command is preset in the logic control circuit 120, The pressure information can include multiple types and is not limited. It can be set according to actual needs, such as the distribution capacity. The default correspondence is the material category selection corresponding to the pressure information, the distribution capacity, etc. The user first presets the corresponding pressure information To define the material category and distribution capacity to be distributed, after preset execution conditions, the user only needs to detachably fix the container on the pressure sensing component 110 to trigger the pressure sensing component 110 to send a signal to the logic control circuit 120, It can allow automatic selection of the distribution material category, or automatic execution of the capacity and amount of the distribution material. It can be applied to all kinds of water, beverages, or other liquid/semi-liquid/solid materials that can be distributed. It is especially suitable for fast and Frequently used occasions (such as restaurants, fast-food stores and other multi-travel business environments), after the first preset is completed, the need to allocate different material types can be omitted. Each time the manual needs to manually select individual material categories and allocate materials The distribution control device can control the distribution device to automatically perform the distribution action. After the distribution device performs the distribution action, the user can conveniently take the container away, greatly reducing manual operation time and improving operation efficiency.

In one embodiment, the pressure information includes the pressure position and/or the pressure amplitude, and the logic control circuit 120 is used to receive the pressure position and/or the pressure amplitude, according to the pressure position and/or the pressure amplitude and preset The corresponding relationship sends the feeding control instruction to the corresponding distribution device, and the feeding control instruction is used to control the corresponding distribution device to transfer materials.

Specifically, the pressing position refers to, for example, setting the pressing mechanism 111 at different positions of the pressing sensing component 110. As shown in Figure 2, each position is preset to correspond to a feeding control command, for example, set on the pressing sensing component 110 There are two pressing mechanisms 111, A and B. It can be understood that the pressing mechanism 111 is not limited to two, and can include any number. A pressing mechanism 111 corresponds to distributing 350mL of water, and B pressing mechanism 111 corresponds to 5 Ice cube; pressure amplitude refers to the degree of pressure force for each pressure mechanism 111, and each amplitude is preset to correspond to a feeding control command, such as A pressure mechanism 111 Press to the first gear, that is to dispense 350mL of water, press to the second gear, that is to dispense 400mL of water; or it can be set to A pressure mechanism 111 to dispense 350mL of water, B pressure mechanism 111 to dispense 400mL of water Water is used as another control method, etc., and so on, can be set flexibly, further increasing the convenience of distribution.

In one embodiment, grooves are provided on the inner surface of the pressure sensing component 110, and protrusions are provided at corresponding positions on the outer surface of the container; or protrusions are provided on the inner surface of the pressure sensing component 110, and grooves or protrusions are provided at corresponding positions on the outer surface of the container. Or set grooves and protrusions on the inner surface of the pressure sensing component 110, and set protrusions and grooves or protrusions at corresponding positions on the outer surface of the container.

Specifically, as shown in Figure 3, the convex position can be set on the bottom or side of the container, the concave position can be set on the bottom or the side of the container, and the pressure sensing component 110 corresponding to the convex position on the bottom of the container is set at the bottom for use as Matching and allowing self-reaction to identify the required material type, the capacity to be distributed, the concave or convex position set by the amount, and so on, the pressure sensing component 110 is set at the bottom of the container corresponding to the concave position at the bottom for matching and allows itself The reaction is used to identify the required material category, the allocated capacity, and the convex position set by the amount. The pressure sensing component 110 corresponding to the concave position on the side of the container is set on the side for matching and allows its own reaction to identify the required material type and distribution The convex position set for the capacity and volume of the pressure-sensitive component 110 corresponds to the convex position on the side of the container. The concave position is set on the side for matching and allowing self-reaction to identify the required material type, distributed capacity, and volume. Or convex. It is a schematic diagram of the structure of the container body and the pressure sensing assembly 110 in one of the cases.

It can be understood that the position, shape and amount of the concave and convex parts of the container and the position, shape and amount of the concave and convex parts of the sensing component exemplified in the above description are not limited to the examples cited in the description, and can be applied to the actual design application environment. The requirement defines the matching position as concave or convex, the amount of the concave-convex part relative to the pairing, and the position where the concave-convex part is located in the container and the sensing component. The concave-convex part is not limited in shape.

Further, the description is given by taking as an example the protrusions on the inner surface of the pressure sensing component 110 and the grooves on the outer surface of the container. The user first presets the material types, distribution capacities, and quantities required for the containers with different amounts of protrusions. Executing specifications, this allows the logic control circuit 120 to execute the preset requirements according to the storage, that is, according to the preset conditions in the follow-up, for example, a container with two convex positions at the specified position, the user sets the preset to be assigned 350mL Distribute 5 ice cubes. The user places the container with the pressure sensing component 110 aligned with the convex position (that is, corresponding to the pressure position in the pressure information), and triggers the pressure sensing component 110 to generate pressure information to The logic control circuit 120 controls the dispensing device to dispense 350 mL of water and 5 ice cubes according to preset conditions. As shown in Figure 4, the protruding position at the bottom of the container will press the pressing mechanism of the pressing sensing assembly 110 (in this example, the button (ie pressing mechanism, hereinafter referred to as button) A and button C are pressed down, The button B side is not pressed down). At this time, as shown in Figure 5, the logic control circuit 120 obtains the signals of pressing the buttons A and C of the sensing component 110. There is no signal of B, and the recognition is performed according to the user's preset , It is necessary to dispense 350mL of water and 5 ice cubes. As shown in Figure 6, when it is detected that 350mL of water and 5 ice cubes are distributed, the logic control circuit 120 will stop the dispensing action, and then the user You can randomly place individual containers that have been pre-set for material category and distribution to trigger automatic execution of pre-set instructions. In other embodiments, the protrusions provided on the sides of the container will push the opposing pressure sensing components 110 (in this example, button A and button C are pushed, and button B is not pushed); in other embodiments , The recess provided at the bottom of the container will accommodate the relative sensing component (in this example, button A and button C are accommodated in the recess space without being pressed, but button B has no space to accommodate and is pressed); in other embodiments , The recess provided on the side of the container will accommodate the relative sensing component (in this example, button A and button C are accommodated in the recess space but not pushed, but button B has no space to accommodate and is pushed). The distribution material outlets exemplified in the description of this application are not limited or specified, and the pressing, pressing, and pushing parts of the sensing components are not limited to this description. The examples in the description can be determined according to individual application requirements.

In one embodiment, as shown in FIG. 7, the pressure sensing assembly 110 includes a tray, a pressure mechanism, a magnetic induction switch integrated circuit 112, and a magnet 113. The pressure mechanism is provided on the tray, and the magnet 113 is provided on the pressure mechanism, and It is arranged 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 pressing mechanism is used to move with the pressure of the container. The magnetic induction switch integrated circuit 112 is used to change the magnetic force induced when the magnet 113 is pressed. The pressure information is generated and sent to the logic control circuit 120.

Specifically, the relative arrangement can be arranged relatively vertically or relatively horizontally. The magnet 113 is arranged in the pressing mechanism. When the pressing mechanism is pressed, pressed, or pushed close to the electronic components of the magnetic induction switch integrated circuit 112, the magnetic force of the magnet 113 Increase until the magnetic induction switch integrated circuit 112 element senses sufficient magnetic force, the output of the magnetic induction switch integrated circuit 112 element will produce a voltage change and convert it into pressure information, allowing the logic control circuit 120 to distinguish the state change, and then according to the received The pressing information controls the distribution device to perform corresponding operations.

In one embodiment, as shown in Figure 8, the pressure sensing component 110 includes a tray, a pressure mechanism, a current sensing integrated circuit 114, and a conductive component 115. The pressure mechanism is disposed on the tray, and the conductive component 115 is disposed on the pressure mechanism. , And arranged opposite to the current sensing integrated circuit 114, the current sensing integrated circuit 114 is connected to the logic control circuit 120, the pressing mechanism is used to follow the pressure of the container to move, and the current sensing integrated circuit 114 is used to sense when the conductive component 115 is pressed The change in current generates pressure information and sends it to the logic control circuit 120.

Specifically, the conductive element 115 is arranged in the pressure mechanism. When the pressure mechanism is pressed, pressed or pushed to contact the current sensing integrated circuit 114 to generate current conduction, the current sensing integrated circuit 114 will be converted into pressure due to the current change. Capital According to the information, the logic control circuit 120 can distinguish the state change, and control the distribution device to perform the corresponding operation according to the received pressure information.

In one embodiment, as shown in Figure 9, the pressure sensing component 110 includes a tray, a pressure mechanism, a pressure component, and a piezoelectric sensing integrated circuit 116. The pressure mechanism is disposed on the tray, and the pressure component is disposed on the pressure. The piezoelectric induction integrated circuit 116 is connected to the logic control circuit 120, and the pressure mechanism moves with the pressure of the container. The piezoelectric induction integrated circuit 116 is used for pressing according to the pressure of the pressure component. The sensed voltage or current change generates corresponding pressure information and sends it to the logic control circuit 120.

Specifically, the pressing component is arranged in the pressing mechanism. When the pressing mechanism is pressed, pressed or pushed to the piezoelectric induction integrated circuit 116 to apply pressure, the piezoelectric induction integrated circuit 116 will be affected by the applied pressure. The pressure produces a certain output (voltage/current) change and converts it into pressure information, allowing the logic control circuit to distinguish the state change, so as to control the distribution device to perform corresponding operations according to the received pressure information.

In one embodiment, as shown in Figure 10, the pressure sensing component 110 includes a tray, a pressure mechanism, a pressure component 117, and a circuit switch 118. The pressure mechanism is disposed on the tray, and the pressure component 117 is disposed on the pressure mechanism. , And set opposite to the circuit switch 118, the circuit switch 118 is connected to the logic control circuit 120, the pressing mechanism moves with the pressure of the container, and the circuit switch 118 is used to generate a corresponding response according to the state change of the circuit when the pressing component 117 is pressed. The pressure information is sent to the logic control circuit 120.

Specifically, the pressing component 117 is provided in the pressing mechanism. When the pressing mechanism is pressed, pressed, or pushed to the circuit switch 118, the circuit switch 118 will change state due to the applied pressing, and the switch state will be changed. Change into pressure The information allows the logic control circuit 120 to distinguish the change of the state, so as to control the distribution device to perform corresponding operations according to the received pressure information.

In one embodiment, the pressure sensing component 110 may be a tray, a pressure mechanism, a conductive component, and a general circuit. The pressure mechanism is arranged on the tray, and the conductive component is arranged on the pressure mechanism, and is arranged opposite to the general circuit, and the general circuit is connected. The logic control circuit 120, the conductive component is arranged in the pressing mechanism, when the pressing mechanism is pressed, pressed or pushed to contact the general circuit closed circuit, the logic control circuit 120 can distinguish the change of the state, and then according to the received pressure The movement information controls the distribution device to perform the corresponding operation.

The electronic induction methods exemplified above are not limited to the examples given. In particular, there are many electronic induction methods, which can be implemented by other electronic induction methods. The sensing component in this application is only set as an example with simple on/off logic. The sensing method can also be set as the pressure, pressing, and pushing amplitude of the sensing part to be used as different units to identify the required individual assignment instructions Perform actions.

The above distribution control equipment, taking into account the current global economic situation, many businesses (restaurants, coffee shops, bars, etc.) are also trying to reduce operating costs as much as possible. Therefore, it can bring the following economic advantages: a substantial reduction in the selection of material types and distribution Capacity, quantity, time and material wastage due to human error; reduce the ratio of the time required by employees, waiters, etc. (especially in the case of hourly wage calculation) to prepare the allocation of materials such as beverages, so as to allow more time Arrange for other tasks, which may reduce the required staff costs; compared with traditional distribution equipment and machines, it can allow a single container to be placed in multiple distribution ports without the need for distribution ports for individual material categories To occupy the area, so as to omit the location of multiple distribution outlets.

In one embodiment, as shown in Figure 10, a distribution device, It includes a distribution device 300 and the aforementioned distribution control device 100. The distribution control device 100 is connected to the distribution device 300. The distribution device 300 is used to receive feeding control instructions, and extract materials and deliver them according to the feeding control instructions.

Specifically, the distribution device 300 is used to extract the corresponding material according to the feeding control instruction sent by the distribution control device 100 and transfer it to the container, and according to the stop feeding control instruction sent by the distribution control device 100, stop extracting the corresponding material and transfer it to the container. To complete the material distribution process.

In one embodiment, as shown in Figure 11, the distribution 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, and the feeding control device 320 is communicatively connected to the distribution control device 100. The device 320 is used for receiving a feeding control instruction, extracting a corresponding amount of material from the material storage container 310 according to the feeding control instruction and transmitting it, receiving a feeding stop control instruction, and stopping extracting materials according to the feeding stop control instruction.

Specifically, the material storage container 310 is a liquid, semi-liquid or solid storage container. A distribution device can include multiple material storage containers 310, which can be combined and matched according to actual needs. For example, it includes both a semi-liquid and a solid storage container. The specific type is not limited, and it may be liquids such as water and beverages, semi-liquid such as ice cream, smoothies, and soft ice cream, or solids such as ice cubes and sugar granules.

In one embodiment, as shown in Figures 12 and 13, the feeding control device 320 includes a pump 322 and/or a quantity distribution device 324. When the feeding control device 320 includes a pump 322 and a quantity distribution device 324, the material storage container 310 includes The liquid/semi-liquid material storage container 312 and the solid material storage container 314, the distribution device 300 also includes a material conveying device 330, the liquid/semi-liquid material storage container 312 is connected to the pump 322 through the material conveying device 330, and the solid material storage container 314 is connected The quantity distribution device 324, the pump 322 and the quantity distribution device 324 are connected to the distribution control device; when the feeding control device 320 is the pump 322, the material storage container 310 is a liquid/semi-liquid material storage container 312, and the distribution device 300 also includes a material conveying device 330 , The liquid/semi-liquid material storage container 312 is connected to the pump 322 through the material conveying device 330, and the pump 322 is connected to the distribution control device 100; when the feeding control device 320 is the quantity distribution device 324, the material storage container 310 is the solid material storage container 314. The material storage container 314 is connected to the distribution control device 100 through the quantity distribution device 324.

Specifically, when the material is liquid or semi-liquid, the corresponding material storage container 310 is the liquid/semi-liquid material storage container 312, and the corresponding feeding control device 320 is the pump 322. When the material is solid, the corresponding material storage The container 310 is a solid material storage container 314, and the corresponding feeding control device 320 is a quantity distribution device 324. When the feeding control device 320 includes a pump 322, it also includes a material conveying device 330. 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 Figures 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, and the fixing member 12 is fixedly arranged in the upper body 10. On the bottom surface, the lifting member 11 is arranged inside the fixing member 12 and can move up and down. The side wall of the lifting member 11 is provided with a circulation hole 16, and the middle of the lifting member 11 has a filling circulation channel 15 which passes through the bottom of the upper body 10. The lower body 20 includes a cover plug 21, a rigid cylinder 22, the cover plug 21 is fixedly connected to the rigid cylinder 22, the rigid cylinder 22 has a channel inside, and the outer side wall of the cover plug 21 can be engaged with the inner side wall of the lifting member 11.

Further, the upper body 10 includes a fixing part 12 and a lifting part 11. The fixing part 12 is fixedly arranged on the inner bottom surface of the upper body 10. The lifting part 11 is arranged inside the fixing part 12 and can move up and down. In this embodiment, the fixing part 12 , The lifting parts 11 are round The ring shape can of course also be arranged in other shapes; the side wall of the lifting member 11 is provided with a circulation hole 16 for realizing filling, the middle of the lifting member 11 has a filling circulation channel 15, the filling circulation channel 15 passes through the bottom of the upper body 10.

The lower body 20 includes a cover plug 21, a rigid cylinder 22, an outer ring telescopic tube 24, an inner ring telescopic tube 26, an internal channel 28, and a connecting hose 29. The outer ring telescopic tube 24 includes a top plate 24a, a bottom plate 24b, and a connection between the two The side wall 24c, the top plate 24a and the bottom plate 24b are provided with a spring 25, the top plate 24a and the bottom plate 24b are provided with a spring 25, the rigid column 22 is provided on the top plate 24a, the rigid column 22 is made of strong materials, which can play a supporting role That is, if stainless steel materials are used, they will not rust easily. The rigid cylinder 22 has a channel inside. The inner ring telescopic tube 26 is arranged inside the outer ring telescopic tube 24 and communicates with the rigid cylinder 22. The inner ring telescopic tube 26 is made of elastic materials, such as rubber materials, and the cost of using rubber materials is low, and Good flexibility and long service life. The spring 25 is located outside the inner ring telescopic tube 26, a second leak-proof ring 212 is provided at the connection between the rigid column 22 and the top plate 24a, a supporting base 27 is provided on the bottom plate 24b, and a supporting column 23 is provided on the supporting base 27. 23 passes through the inner ring telescopic tube 26 and extends into the rigid cylinder 22. The top of the support column 23 is fixedly provided with a cover plug 21, and the cover plug 21 is fixedly connected to the top of the rigid cylinder 22. A first leak-proof ring 211 is provided at the connection, the rigid cylinder 22 is located inside the lifting member 11, and the outer side wall of the cover plug 21 and the inner side wall of the top of the lifting member 11 are engaged by the engagement of the locking position 14 and the convex position 210. In this embodiment, the locking position 14 is provided on the inner side wall of the top of the lifting member 11, and the convex position 210 is provided on the outer side wall of the cover plug 21. The internal channel 28 is fixedly connected to the bottom plate 24b and communicates with the rigid cylinder 22, and the connecting hose 29 communicates with the bottom of the internal channel 28.

Specifically, when the material conveying device 330 is used, it is used in conjunction with the feeding control device 320 and presses the upper body 10 downward. The fixing member 12 moves down with the upper body 10, and the rigid cylinder 22 drives the lifting member 11 to move up through the cover plug 21. , The circulation hole 16 is exposed to In addition, at this time, the liquid/semi-liquid can flow from the lower body 20 to the upper body 10 and be discharged from the circulation hole 16, thereby realizing the work of filling. The material conveying device 330 can be applied to the filling of various types of water, beverages, or other liquid/semi-liquid, ice cream machines and smoothies. The filling speed is fast, the efficiency is high, and the safety performance is high. For example, it can reduce the high temperature liquid transportation The problem of splashing during the time, and then burns the user; at the same time, the method of pouring from the bottom up reduces the leakage during the pouring, and greatly reduces the foam generated by the carbonated liquid during the pouring, so that no liquid is required Backflow action; equipped with a simple natural flow principle, the upper body in this design is poured from the liquid supply source; the application of this design can break through the traditional beverages, beverages and other liquids, as well as semi-liquid materials from top to bottom The lower pouring method is easy to operate.

In one embodiment, as shown in Figure 14, when the feeding control device 320 is a pump 322, the distribution device 300 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 the feeding control instruction. The material is extracted from the material storage container 310 according to the feeding control instruction and transferred, including: the pump 322 receives the feeding control instruction, and the material conveying device 330 is controlled according to the feeding control instruction to extract the material from the liquid/semi-liquid material storage container 312 and send it to the temperature control device 340: The temperature control device 340 controls the temperature of the received material to a preset temperature and then transmits it.

Specifically, when the material is liquid or semi-liquid, the temperature control device 340 is used to control the temperature of the material. When the distribution equipment includes the temperature control device 340, correspondingly, the control instruction includes corresponding temperature control information, and the pump 322 receives The feeding control command controls the material conveying device 330 to extract the material from the liquid/semi-liquid material storage container 312 and transfer it to the temperature control device 340 according to the feeding control command; the temperature control device 340 transfers the material after controlling the temperature of the received material to a preset temperature.

In one embodiment, as shown in Figure 14, the distribution device also includes Including the flow detection device 350, the flow detection device 350 is in communication with the distribution control device 100. The flow detection device 350 is used to detect the flow of the material and send the flow to the distribution control device 100; the distribution control device 100 receives the flow, and when the flow is detected When the preset flow rates are inconsistent, the flow control instruction is sent to the pump 322 until the flow rate fed back by the flow detection device 350 is consistent with the preset flow rate; the pump 322 is used to control the distribution flow according to the received flow control instruction.

Specifically, the specific type of the flow detection device 350 is not limited. According to the type of material, the corresponding flow detection device 350 will feed back the flow of the material to the logic control circuit 120 to ensure that the distribution capacity is correct. The applicable scope of this application includes, but is not limited to: various liquid distribution applications (such as drinking water, beverage capacity), various semi-liquid distribution applications (such as smoothie drinks, soft ice cream capacity) and various solids Distribution application (such as the amount of ice cubes, sugar granules).

In actual application, as shown in Figure 17, taking the liquid/semi-liquid material storage container 312 and the solid material storage container 314 as an example for description, the specific process is as follows: 1. The container is placed on the designated position of the dispensing equipment; 2. The convex position at the bottom of the container will press down the opposing pressing mechanism (button a and button c are pressed down, but the button b side is not pressed down), at this time, the relevant signal is transmitted to the logic control circuit; further , The container can be a special container or an ordinary container. When it is an ordinary container, the device matching the pressing mechanism can be detachably fixed at the corresponding position of the ordinary container, so that the corresponding pressing mechanism can be pressed down; 3. Logic The control circuit operates according to the state signal of the sensor component pressed down at the bottom of the container, starts the water pump (not shown), the motor (corresponding to the feeding control device 320) to dispense water, and sends instructions to the ice cube dispensing meter (corresponding to the feeding control device 320) Distribute only 5 ice cubes; 4. When the designated water pump motor is started, the corresponding flow meter will feed back the water flow to the logic control circuit. When the capacity reaches 350mL, the logic control circuit will stop the water pump motor and stop dispensing water; 5 , Therefore, when 350mL capacity of water, in 5 After the ice cubes have been dispensed/distributed into the container, the execution of the action command is completed, and the distributing device will automatically stop after completing a set of commands. The user can directly take the dispensed/distributed container.

The above-mentioned distribution control device and distribution equipment is an innovative automatic capacity and volume recognition distribution structure principle that promotes efficiency and is not limited to various types of water, beverages, or other liquid/semi-liquid/solid Such as materials that can be distributed and distributed), especially suitable for occasions that require rapid and frequent use (such as restaurants, fast-food stores and other business environments with many people). After the first preset is completed, it is possible to omit the steps to manually select individual material categories, allocate and distribute the capacity and quantity of materials, such as those used in restaurants on the market, for different material categories, allocation and distribution requirements. In the soda machine, the waiter in the restaurant needs to manually select the individual required dispenser capacity buttons on the soda machine according to the type of beverage ordered by the customer and the capacity (large, medium and small) cups, but this allocation can inform the device and the dispensing equipment can be omitted The waiter needs to manually select the step of pressing the individual allocation button each time, which can relatively greatly reduce the operation time of the waiter and promote operational efficiency.

The technical features of the above embodiments can be combined arbitrarily. In order to make the description concise, all possible combinations of the technical features in the above embodiments are not described. However, as long as there is no contradiction between the combinations of these technical features, they should It is considered as the range described in this specification.

The above examples only express several implementation manners of the present application, and the description is relatively specific and detailed, but it should not be understood as a limitation on the scope of the invention patent. It should be pointed out that for those of ordinary skill in the art, without departing from the concept of this application, several modifications and improvements can be made, and these all fall within the protection scope of this application. Therefore, the scope of protection of this patent application shall be subject to the scope of the attached patent application.

110‧‧‧Pressure Sensing Components

120‧‧‧Logic control circuit

Claims (10)

A distribution control device, characterized in that it comprises a pressure sensing component and a logic control circuit, the pressure sensing component is connected to the logic control circuit, the logic control circuit is used to connect to a distribution device, and the pressure sensing component is used for detachable fixing The matched container moves when the container is pressed down. The pressure sensing component is used to obtain pressure information based on the detection when the container is pressed down, and send the pressure information to the logic control circuit; the logic control circuit uses After receiving the pressure information, a feeding control instruction is sent to the distribution device according to the pressure information and a preset corresponding relationship. The feeding control instruction is used to control the distribution device to deliver materials, wherein the preset corresponding relationship is the pressure information And the corresponding relationship between the feeding control command; and after detecting that the dispensing device completes the feeding operation, a feeding stop operation command is generated to the dispensing device, and the feeding stop control command is used to control the dispensing device to stop feeding materials; wherein the pressure The motion information includes the pressure position and/or the pressure amplitude, and the logic control circuit is used to receive the pressure position and/or the pressure amplitude, and send according to the pressure position and/or the pressure amplitude and the preset correspondence relationship The feeding control instruction is sent to the corresponding distribution device, and the feeding control instruction is used to control the corresponding distribution device to transfer materials. The distribution control device according to item 1 of the scope of patent application, wherein the pressure sensing component includes a tray, a pressure mechanism, a magnetic induction switch integrated circuit, and a magnet. The pressure mechanism is arranged on the tray, and the magnet is arranged on the pressure. The magnetic induction switch integrated circuit is arranged opposite to the magnetic induction switch integrated circuit, the magnetic induction switch integrated circuit is connected to the logic control circuit, the pressing mechanism is used to follow the pressure of the container to move, and the magnetic induction switch integrated circuit is used to move according to the pressure of the magnet The induced magnetic force changes generate pressure information and send it to the logic control circuit. According to the distribution control device described in item 1 of the scope of patent application, the pressure sensing component includes a tray, a pressure mechanism, a current sensing integrated circuit, and a conductive component. The pressure mechanism is disposed on the tray, and the conductive component is disposed on the tray. The pressing mechanism is arranged opposite to the current sensing integrated circuit, the current sensing integrated circuit is connected to the logic control circuit, the pressing mechanism is used to follow the pressure of the container to move, and the current sensing integrated circuit is used to move according to the conductive component The current change induced during compression generates compression information and sends it to the logic control circuit. The distribution control device according to the first item of the scope of patent application, wherein the pressure sensing component includes a tray, a pressure mechanism, a pressure component and a piezoelectric induction integrated circuit, the pressure mechanism is arranged on the tray, and the pressure component It is arranged in the pressing mechanism and opposite to the piezoelectric induction integrated circuit. The pressing induction integrated circuit is connected to the logic control circuit. The pressing mechanism moves with the pressure of the container. The piezoelectric induction integrated circuit is used for The corresponding pressure information is generated according to the voltage or current change induced when the pressure component is compressed and sent to the logic control circuit. For the distribution control device described in item 1 of the scope of patent application, the pressure sensing component includes a tray, a pressure mechanism, a pressure component, and a circuit switch. The pressure mechanism is disposed on the tray, and the pressure component is disposed on the tray. The pressing mechanism is arranged opposite to the circuit switch. The circuit switch is connected to the logic control circuit. The pressing mechanism moves with the pressure of the container. The circuit switch is used to switch the circuit when the pressing component is pressed. The change of the state generates corresponding pressure information and sends it to the logic control circuit. A distribution device, characterized in that it comprises a distribution device and a distribution control device as described in any one of items 1 to 5 in the scope of the patent application, the distribution control device is connected to the distribution device, and the distribution device is used for receiving feeding control instructions , According to the feeding control instruction to extract materials and transmit. For example, the distribution device described in item 6 of the scope of patent application, wherein the distribution device includes a material storage container and a feeding control device, the material storage container is connected to the feeding control device, the feeding control device is communicatively connected to the distribution control device, and the feeding control device The device is used for receiving a feeding control instruction, extracting a corresponding amount of material from the material storage container according to the feeding control instruction and transmitting it; and receiving a feeding stop control instruction, and stopping extracting materials according to the feeding stop control instruction. For the dispensing equipment described in item 7 of the scope of patent application, the feeding control device includes a pump and/or a quantity distribution device. When the feeding control device includes the pump and the quantity distribution device, the material storage container includes a liquid/semi- The liquid material storage container and the solid material storage container, the distribution device further includes a material conveying device, the liquid/semi-liquid material storage container is connected to the pump through the material conveying device, the solid material storage container is connected to the quantity distribution device, the pump and The quantity distribution device is connected to the distribution control device; when the feeding control device is the pump, the material storage container is the liquid/semi-liquid material storage container, and the distribution device further includes the material conveying device, and the liquid/semi-liquid material The storage container is connected to the pump through the material conveying device, and the pump is connected to the distribution control device; when the feeding control device is the quantity distribution device, the material storage container is the solid material storage container, and the solid material storage container passes through the quantity The distribution device is connected to the distribution control device. For example, the distribution equipment described in item 8 of the scope of patent application, when the feeding control device is the pump, further includes a temperature control device, the material conveying device is connected to the temperature control device, the pump receives the feeding control instruction, and according to the feeding control device The control instruction extracts the material from the material storage container and transmits it, including: the pump receives the feeding control instruction, and controls the material conveying device according to the feeding control instruction to extract the material from the liquid/semi-liquid material storage container and deliver it to the temperature Control device; the temperature control device is controlling the received material The temperature is sent to the preset temperature. For example, the distribution equipment described in item 9 of the scope of patent application further includes a flow detection device which is communicatively connected to the distribution control device. The flow detection device is used to detect the flow rate of the material and send the flow rate to the distribution control device. Device; the distribution control device is used to receive the flow, when it is detected that the flow is inconsistent with the preset flow, send a flow control instruction to the pump until the flow returned by the flow detection device is consistent with the preset flow; the pump is used According to the received flow control instruction, the flow is controlled and distributed.

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