CN117366937A - Ice machine weighing device and system - Google Patents

Abstract

The application provides an ice maker weighing device and system. This ice maker weighing device includes: the ice quantity control circuit comprises a first switching device arranged in the ice maker and a second switching device arranged in the ice maker weighing equipment, the first switching device and the second switching device are connected in series in a passage between a Hall switch on an ice baffle of the ice maker and a main control board of the ice maker, the first switching device and the second switching device are arranged in parallel, and the first switching device and the second switching device are electrically connected with the main controller; the main controller is configured to control the first switching device to be switched off and control the second switching device to be switched on or off according to the ice storage amount detected by the weighing piece under the condition that the ice maker works in a first designated time period, so that the ice maker is controlled; and controlling the first switching device to be closed when the ice maker is operated for a second designated period of time, thereby restoring autonomous control of the ice maker.

Description

Ice machine weighing device and system

Technical Field

The embodiment of the application relates to the technical field of ice machines, in particular to an ice machine weighing device and system.

Background

The ice maker is a device for converting internal liquid water into ice cubes by cold and heat exchange through a refrigerating system, and comprises four parts (a compressor, an evaporator, a condenser, a throttling device) and the like; after the refrigerating system works, the evaporator absorbs heat to the outside, liquid water in the evaporator is further converted into ice cubes, and the produced ice cubes are conveyed to the ice storage barrel by the evaporator for storage.

At present, the store ice consumption in winter is small, and the ice maker is in a full ice state under most conditions, so that the store needs to scoop out a large amount of ice when cleaned every week, which is time-consuming and labor-consuming and causes waste of resources.

Based on this, it is an object of the present application to provide a new solution to solve the existing technical drawbacks.

Disclosure of Invention

Based on the above, the embodiment of the application provides the weighing equipment and the system of the ice machine, which can realize the intelligent control of the ice storage amount of the ice machine in a specified time period and save resources.

In a first aspect, embodiments of the present application provide an ice maker weighing apparatus, comprising: the ice quantity control circuit comprises a first switching device arranged in the ice machine and a second switching device arranged in the ice machine weighing equipment, the first switching device and the second switching device are both connected in series in a passage between a Hall switch on an ice baffle of the ice machine and a main control board of the ice machine, the first switching device and the second switching device are arranged in parallel, and the first switching device and the second switching device are also electrically connected with the main controller;

wherein the weighing piece is configured to detect the ice storage amount of the ice maker;

the main controller is configured to control the first switching device to be opened and control the second switching device to be closed or opened according to the ice storage amount under the condition that the ice maker works in a first designated time period, so that the ice maker is controlled;

the main controller is further configured to control the first switching device to be closed when the ice maker is operated for a second designated period of time, thereby restoring autonomous control of the ice maker.

In one embodiment, the first switching device and the second switching device are normally closed relays.

In one embodiment, the method further comprises: a drainage assembly;

wherein the drain assembly is configured to drain condensed water in an ice storage bucket of the ice maker.

In one embodiment, the drain assembly includes: the device comprises a water storage device, a liquid level detection piece and a drainage pump, wherein the water storage device is configured to collect condensed water in an ice storage barrel of the ice machine, the liquid level detection piece is arranged in the water storage device, and the drainage pump is electrically connected with the liquid detection piece;

triggering the drainage pump to start to drain condensed water in the water storage device when the water level information detected by the liquid level detection piece meets a first preset condition;

triggering the drainage pump to stop when the water level information detected by the liquid level detection part meets a second preset condition.

In one embodiment, a filter is provided at the pumping point of the drain pump.

In one embodiment, the main controller is also connected with a Hall switch on the ice baffle of the ice machine, and the working state of the ice machine is perceived through the change of a Hall switch signal.

In one embodiment, the method further comprises: the water leakage detection part and the alarm device can alarm when the water leakage detection part detects that the working environment where the ice machine is located is leaked.

In one embodiment, the method further comprises: the temperature detection piece and the data transmission module are electrically connected with the main controller;

wherein the temperature detecting member is configured to detect an operating environment temperature of the ice maker;

the data transmission module is configured to send the data of the ice maker to a background server.

In one embodiment, the data includes at least one of: the ice storage amount of the ice maker, the operating state of the ice maker, and the operating environment temperature of the ice maker.

In a second aspect, an embodiment of the present application provides an ice maker weighing system, including an ice maker weighing device and a background server provided in the first aspect of the embodiment of the present application, where the background server is electrically connected to the ice maker weighing device.

According to the technical scheme provided by the embodiment of the application, the weighing piece is used for detecting the ice storage amount of the ice machine, when the ice machine works in a first appointed time period, the main controller controls the first switching device in the ice amount control circuit to be switched off, and controls the second switching device to be switched on or switched off by combining the ice storage amount provided by the weighing piece, so that the ice storage amount of the ice machine is controlled by the ice machine weighing equipment, for example, when the ice amount used in winter is small, the ice machine weighing equipment can be used for controlling the ice machine to make ice or stop, so that the ice storage amount of the ice machine meets the use requirement in winter, and the problem that the ice storage amount of the ice machine used in winter is too high is solved; and under the condition that the ice maker works in the second designated time period, the main controller controls the first switching device to be closed, so that the automatic control of the ice maker is recovered, for example, when the ice consumption in summer is high, the control of the ice maker weighing equipment on the ice maker can be released, and the ice storage quantity of the ice maker is automatically controlled by the ice maker, so that the ice consumption in summer is not influenced. That is, the technical scheme provided by the embodiment of the application can realize the intelligent control of the ice storage amount of the ice machine in a specified time period, and resources are saved.

Drawings

Fig. 1 is a schematic structural diagram of an ice maker according to an embodiment of the present disclosure;

FIG. 2 is a schematic diagram of a weighing device of an ice maker according to an embodiment of the present disclosure;

FIG. 3 is a schematic diagram of a structure of an ice amount control circuit according to an embodiment of the present disclosure;

fig. 4 is another schematic structural view of an ice maker weighing device according to an embodiment of the present disclosure;

FIG. 5 is a schematic view of a drain assembly according to an embodiment of the present disclosure;

FIG. 6 is a schematic diagram of another embodiment of a weighing apparatus for an ice maker according to the present disclosure;

FIG. 7 is a schematic diagram of an ice maker system according to an embodiment of the present disclosure;

reference numerals illustrate:

100: an ice maker weighing device; 110: a weighing piece; 120: an ice amount control circuit;

130: a main controller; 140: a drainage assembly; 150: a water leakage detecting member;

160: an alarm device; 170: a temperature detecting member; 180: a data transmission module;

200: a background server; 300: an ice maker weighing system; 1201: a first switching device;

1202: a second switching device; 1401: a water storage device; 1402: a liquid level detecting member; 1403 a drain pump.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the technical solutions in the embodiments of the present application are further described in detail by the following embodiments with reference to the accompanying drawings. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the present application. It should be further noted that, for convenience of description, only some, but not all of the structures related to the present application are shown in the drawings.

For the convenience of understanding of those skilled in the art, the following description will first be given of an ice making control process of the ice maker itself:

the ice-blocking plate of the ice-making machine is provided with a Hall switch, and the ice-making machine has an opening and closing process of the ice-blocking plate every ice-making plate, for example, the ice-blocking plate is opened for a short time and then closed again to represent an ice-dropping process of the ice-making machine, the ice-blocking plate is opened for a long time to represent that the ice-making machine is in a full ice state, and the ice-blocking plate is closed to represent that the ice-making machine is working. The opening and closing state of the ice baffle can be transmitted to the main control board of the ice machine through the Hall switch, namely the main control board of the ice machine can realize ice making control of the ice machine by collecting the on-off state of the Hall switch on the ice baffle.

The specific control principle is as follows: as shown in fig. 1, when an ice making machine makes ice, an ice baffle of the ice making machine is closed, a hall switch (S1) is turned on, and a voltage signal collected by an I/O port (or a 1 interface of a main control board P1 of the ice making machine) is 0 v; when the ice maker is full of ice, the last ice plate falls off to push the ice baffle plate, ice cubes stored in the ice storage barrel block the ice baffle plate from returning, the Hall switch (S1) is disconnected, and the I/O port collects a voltage signal as VDD volts; in the normal ice making circulation process, the voltage signal that the I/O mouth gathered is 0 volt, when making first edition ice, the ice-cube begins to fall into the ice storage barrel, at this moment ice-cube impacts the ice baffle, the ice baffle pops open, hall switch (S1) opens, the voltage signal that the I/O mouth gathered is VDD volt this moment, the ice-cube falls into the ice storage barrel completely, the ice baffle is closed, hall switch (S1) switches on, the voltage signal that the I/O mouth gathered is 0 volt, namely every ice making circulation has a process that I/O mouth voltage signal is 0 volt-transient VDD volt-0 volt.

At present, the store ice consumption in winter is small, and the ice maker is in a full ice state under most conditions, so that the store needs to scoop out a large amount of ice when cleaned every week, which is time-consuming and labor-consuming and causes waste of resources. To this end, the embodiment of the application provides an ice maker weighing device, which can be placed at the bottom of an ice maker, can monitor the capacity of the ice maker in unit time, and can control the ice storage amount of the ice maker in a specified time period.

Fig. 2 is a schematic structural diagram of an ice maker weighing apparatus 100 according to an embodiment of the present application. As shown in fig. 2, the ice maker weighing apparatus 100 includes: the ice amount control circuit 120 comprises a first switch device 1201 arranged in the ice maker and a second switch device 1202 arranged in the ice maker weighing device 100, wherein the first switch device 1201 and the second switch device 1202 are connected in series in a passage between a Hall switch on an ice baffle of the ice maker and a main control board of the ice maker, the first switch device 1201 and the second switch device 1202 are arranged in parallel, and the first switch device 1201 and the second switch device 1202 are electrically connected with the main controller 130.

Specifically, the above-mentioned weighing member 110 is configured to detect the amount of ice stored (or the amount of remaining ice) of the ice maker. Wherein the number and arrangement positions of the weighing pieces 110 are adapted to the actual structure of the ice maker, e.g. the weighing pieces 110 are arranged in the ice maker weighing device 100 at positions matching the support feet of the ice maker. Alternatively, the weighing cell 110 may be a gravity sensor.

Alternatively, the first switching device 1201 and the second switching device 1202 may be normally-closed relays. That is, if no voltage is applied to the first switching device 1201 and the second switching device 1202, the first switching device 1201 and the second switching device 1202 are turned on; conversely, if a voltage is applied to the first switching device 1201 and the second switching device 1202, the first switching device 1201 and the second switching device 1202 are turned off.

By connecting the first switch device 1201 and the second switch device 1202 in series in a path between the hall switch on the ice-blocking plate of the ice maker and the main control plate of the ice maker, the first switch device 1201, the hall switch (S1) and the main control plate of the ice maker form a loop, the second switch device 1202, the hall switch (S2) and the main control plate of the ice maker form another loop, and the main controller 130 can control the working states of the first switch device 1201 and the second switch device 1202, thereby realizing the control of the ice maker. The specific control process is as follows:

first case: when the ice maker operates for a first designated period of time, the main controller 130 controls the first switching device 1201 to be turned off and controls the second switching device 1202 to be turned on or off according to the amount of ice stored provided by the weighing unit 110, thereby achieving control of the ice maker. By controlling the first switching device 1201 to be turned off, the control right of the ice maker is switched from the ice maker main control board to the ice maker weighing apparatus 100, i.e., the ice maker is controlled by the ice maker weighing apparatus 100. Further, when the ice storage amount of the ice maker provided by the weighing unit 110 reaches the first preset threshold, the main controller 130 controls the second switching device 1202 to be turned off, and the ice maker main control board detects that the voltage signal is VDD volts (or high level), that is, the ice blocking board is considered to be in an opened state, so that the ice making is stopped. The ice storage amount in the ice maker decreases with the use of the user, and after a period of time, if the ice storage amount of the ice maker provided by the weighing unit 110 decreases to the second preset threshold value, the main controller 130 controls the second switching device 1202 to be closed (at this time, the hall switch (S1) is also turned on), and the ice maker main control board detects that the voltage signal becomes 0 v (or low level), that is, the ice blocking board is considered to be in a closed state, so that the ice making is started, and the ice use requirement is met.

The first specified period may be set based on the actual ice demand, for example, the first specified period may be a period in which the amount of ice used is small, for example, winter. For example, if the amount of ice used in winter is smaller, the first preset threshold (for example, the first preset threshold is set to be 50 kg) and the second preset threshold (for example, the second preset threshold is set to be 20 kg) may be set based on the ice use requirement of the ice maker in winter, after entering winter, if the ice storage amount of the ice maker provided by the weighing unit 110 reaches the first preset threshold, the main controller 130 controls the second switching device 1202 to be turned off, and the main control board of the ice maker detects that the voltage signal is VDD volt (or high level), that is, the ice baffle is considered to be in an open state, so that the ice making is stopped, and the problem that the ice storage barrel of the ice maker is difficult to clean due to excessive ice amount is avoided. After a certain period of time, if the ice storage amount of the ice maker provided by the weighing unit 110 falls to the second preset threshold value, the main controller 130 controls the second switching device 1202 to be closed, and the ice maker main control board detects that the voltage signal becomes 0 volt (or low level), so that ice making is started to meet the ice demand in winter.

Second case: when the ice maker works in the second designated time period, the main controller 130 controls the first switch device 1201 to be closed, so that the passage between the main control board of the ice maker and the hall switch (S1) is restored, and the autonomous control of the ice maker is realized, i.e. the control right of the ice maker is switched back to the main control board of the ice maker.

The second specified period may be set based on the actual ice demand, and for example, the second specified period may be a period in which the amount of ice used is large, for example, in summer, or may be a period other than the first specified period. Illustratively, when summer comes, the main controller 130 controls the first switching device 1201 to be closed, thereby restoring a path between the main control board of the ice maker and the hall switch (S1), and realizing autonomous control of the ice maker.

It should be noted that, the ice amount control circuit 120 may further include some auxiliary components, such as a voltage dividing resistor, a voltage stabilizing tube, a power supply, etc., and the specific structure of the ice amount control circuit 120 may be seen in fig. 3, and as can be seen from fig. 3, the main controller 130 may control the first switch device 1201 (the first switch device 1201 is disposed on the bridge plate of the ice maker), so as to control the operation of the ice maker by the ice maker weighing device, and control the ice amount of the ice maker by controlling the second switch device 1202 (the second switch device 1202 is disposed in the ice maker weighing device 100) to be turned on or off, and control the ice amount of the ice maker by controlling the first switch device 1201 to be turned off to resume the autonomous control of the ice maker.

In one embodiment, the main controller 130 is optionally further connected to a hall switch (S1) on the ice-blocking plate of the ice maker, and senses the operating state of the ice maker through the change of the signal of the hall switch (S1). For example, an ice baffle of the ice machine is closed, a Hall switch (S1) is conducted, a voltage signal acquired by an I/O port is 0V, and the ice machine can be perceived to be in an ice making state by analyzing the voltage signal; the last ice plate falls off to push away the ice baffle, ice blocks stored in the ice storage barrel block the ice baffle from returning, the Hall switch (S1) is disconnected, and the I/O port collects a voltage signal of VDD volts, so that the ice maker can be perceived to be in a full ice state; if the Hall switch (S1) is closed, temporarily opened and closed, and the voltage signal collected by the I/O port is 0 volt-short VDD volt-0 volt, the ice machine can be perceived to be in a normal ice making circulation state.

In one embodiment, optionally, as shown in fig. 4, the ice maker weighing apparatus further includes: and a drain assembly 140. Wherein the drain assembly 140 is configured to drain condensed water within the ice bank of the ice maker. When the ice machine weighing device 100 is assembled with the ice machine, one end of the water drain assembly 140 can be connected to a condensed water drain pipe of an ice machine ice storage barrel, the other end of the water drain assembly can be connected to a sewer, the ice machine ice storage barrel is isolated from the sewer through the water drain assembly 140, and pollution of the ice machine ice storage barrel caused by odor and sewage backflow of the sewer is avoided.

In one embodiment, optionally, as shown in fig. 5, the drainage assembly 140 may include: the ice maker comprises a water storage device 1401 configured to collect condensed water in an ice storage barrel of the ice maker, a liquid level detection member 1402 and a drainage pump 1403 which are arranged in the water storage device 1401, wherein the drainage pump 1403 is electrically connected with the liquid detection member 1402.

Wherein, the water storage device 1401 is provided with a condensed water receiving port, and is connected with a condensed water drain pipe of the ice storage barrel of the ice machine through the condensed water receiving port so as to collect condensed water in the ice storage barrel of the ice machine. The shape and capacity of the water storage device 1401 may be set based on actual requirements, which is not limited in the present embodiment.

A liquid level detecting member 1402 is provided in the water storage device 1401, and the liquid level detecting member 1402 is configured to detect information of the level of the liquid in the water storage device 1401. Alternatively, the liquid level detecting member 1402 may be a float-type liquid level gauge, a float-type liquid level switch, or the like.

Triggering the starting of the drainage pump 1403 to drain the condensed water in the water storage device 1401 when the liquid level detection piece 1402 detects that the water level information in the water storage device 1401 meets a first preset condition; after the condensed water in the water storage device 1401 is pumped away, the water level in the water storage device 1401 is reduced, and when the water level information detected by the liquid level detecting member 1402 meets a second preset condition (for example, when the water level in the water storage device 1401 is reduced to a preset minimum water level), the drainage pump 1403 is triggered to stop. Through the cooperation of the liquid level detection part 1402 and the drainage pump 1403, the condensed water collected in the water storage device 1401 is timely discharged, and pollution of an ice storage barrel of the ice machine caused by backflow of the condensed water is avoided.

Optionally, the water pumping part of the drain pump 1403 is provided with a filter, through which impurities in the condensed water can be filtered, and the impurities are prevented from entering the inside of the drain pump 1403, thereby improving the efficiency and the service life of the drain pump 1403.

In one embodiment, optionally, as shown in fig. 6, the ice maker weighing apparatus further includes: the water leakage detection piece 150 and the alarm device 160, the water leakage detection piece 150 can be arranged in the working environment where the ice machine is located and used for detecting whether the working environment where the ice machine is located has water leakage or not, and the alarm device 160 can give an alarm when the water leakage detection piece 150 detects that the working environment where the ice machine is located leaks, so that staff is reminded of timely processing the problem of water leakage of a store, and the loss of the store is avoided. Alternatively, the alarm 160 may be a buzzer or the like.

With continued reference to fig. 6, in one embodiment, optionally, the ice maker weighing apparatus further comprises: the temperature detecting member 170 and the data transmission module 180 are electrically connected with the main controller 130.

Wherein the temperature detecting member 170 is configured to detect an operating environment temperature of the ice maker, and the data transmission module 180 is configured to transmit data of the ice maker to the background server. The data transmission module 180 may be a wired transmission module or a wireless transmission module, such as a wireless fidelity (WIreless Fidelity, wiFi) module or a mobile communication module of any standard (such as a 5G module).

Optionally, the data includes at least one of: the ice storage amount of the ice maker, the operating state of the ice maker, and the operating environment temperature of the ice maker. And the data transmission module 180 is used for transmitting the relevant data of the ice maker to the background server, so that the background server monitors the ice maker according to the received data. The background server may allocate a take-out order of a store according to the reported ice storage amount of the ice maker, or determine whether the ice maker works normally according to the reported working environment temperature of the ice maker and the ice making amount of the ice maker in unit time, etc.

In one embodiment, an ice maker weighing system 300 is also provided. As shown in fig. 7, the ice maker weighing system 300 may include: the ice maker weighing device 100 and the background server 200 according to any of the embodiments described above, wherein the background server 200 is electrically connected to the ice maker weighing device 100, and the background server 200 monitors the ice maker according to the related data of the ice maker reported by the ice maker weighing device 100.

According to the technical scheme provided by the embodiment of the application, the weighing piece is used for detecting the ice storage amount of the ice machine, when the ice machine works in a first appointed time period, the main controller controls the first switching device in the ice amount control circuit to be switched off, and controls the second switching device to be switched on or switched off by combining the ice storage amount provided by the weighing piece, so that the ice storage amount of the ice machine is controlled by the ice machine weighing equipment, for example, when the ice amount used in winter is small, the ice machine weighing equipment can be used for controlling the ice machine to make ice or stop, so that the ice storage amount of the ice machine meets the use requirement in winter, and the problem that the ice storage amount of the ice machine used in winter is too high is solved; and under the condition that the ice maker works in the second designated time period, the main controller controls the first switching device to be closed, so that the automatic control of the ice maker is recovered, for example, when the ice consumption in summer is high, the control of the ice maker weighing equipment on the ice maker can be released, and the ice storage quantity of the ice maker is automatically controlled by the ice maker, so that the ice consumption in summer is not influenced. That is, the technical scheme provided by the embodiment of the application can realize the intelligent control of the ice storage amount of the ice machine in a specified time period, and resources are saved.

The technical features of the above-described embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above-described embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The above examples only represent a few embodiments of the present application, which are described in more detail and are not to be construed as limiting the scope of the present application. It should be noted that it would be apparent to those skilled in the art that various modifications and improvements could be made without departing from the spirit of the present application, which would be within the scope of the present application. Accordingly, the scope of protection of the present application is to be determined by the claims appended hereto.

Claims (10)

1. An ice maker weighing apparatus, comprising: the ice quantity control circuit comprises a first switching device arranged in the ice machine and a second switching device arranged in the ice machine weighing equipment, the first switching device and the second switching device are both connected in series in a passage between a Hall switch on an ice baffle of the ice machine and a main control board of the ice machine, the first switching device and the second switching device are arranged in parallel, and the first switching device and the second switching device are also electrically connected with the main controller;

wherein the weighing piece is configured to detect the ice storage amount of the ice maker;

the main controller is configured to control the first switching device to be opened and control the second switching device to be closed or opened according to the ice storage amount under the condition that the ice maker works in a first designated time period, so that the ice maker is controlled;

the main controller is further configured to control the first switching device to be closed when the ice maker is operated for a second designated period of time, thereby restoring autonomous control of the ice maker.

2. The ice maker weighing apparatus of claim 1, wherein said first and second switching devices are normally closed relays.

3. The ice maker weighing apparatus of claim 1, further comprising: a drainage assembly;

wherein the drain assembly is configured to drain condensed water in an ice storage bucket of the ice maker.

4. The ice maker weighing apparatus of claim 3, wherein said drain assembly comprises: the device comprises a water storage device, a liquid level detection piece and a drainage pump, wherein the water storage device is configured to collect condensed water in an ice storage barrel of the ice machine, the liquid level detection piece is arranged in the water storage device, and the drainage pump is electrically connected with the liquid detection piece;

triggering the drainage pump to start to drain condensed water in the water storage device when the water level information detected by the liquid level detection piece meets a first preset condition;

triggering the drainage pump to stop when the water level information detected by the liquid level detection part meets a second preset condition.

5. The ice maker weighing apparatus of claim 4, wherein a water suction portion of said drain pump is provided with a filter.

6. The ice machine weighing apparatus of claim 1 wherein said main controller is further connected to hall switches on ice plates of the ice machine to sense the operational status of the ice machine by hall switch signal changes.

7. The ice maker weighing apparatus of claim 1, further comprising: the water leakage detection part and the alarm device can alarm when the water leakage detection part detects that the working environment where the ice machine is located is leaked.

8. The ice maker weighing apparatus of claim 1, further comprising: the temperature detection piece and the data transmission module are electrically connected with the main controller;

wherein the temperature detecting member is configured to detect an operating environment temperature of the ice maker;

the data transmission module is configured to send the data of the ice maker to a background server.

9. The ice maker weighing apparatus of claim 8, wherein said data includes at least one of: the ice storage amount of the ice maker, the operating state of the ice maker, and the operating environment temperature of the ice maker.

10. An ice maker weighing system comprising an ice maker weighing apparatus as claimed in any one of claims 1 to 9 and a background server, said background server being electrically connected to said ice maker weighing apparatus.