CN218972954U - Microcomputer system for fluidized ice making equipment - Google Patents

Abstract

The utility model provides a microcomputer system for ice making equipment of fluidized ice, which comprises a bearing platform, a main control box, a refrigerator, a speed reducer, a compressor and a condenser, wherein the main control box, the refrigerator, the speed reducer, the compressor and the condenser are arranged on the bearing platform; a compressor rack for installing a compressor is arranged on the bearing platform; the condenser is positioned at the inner side part of the compressor rack; the ice-making device also comprises a refrigerator arranged close to the refrigerator and an ice-drawing pump communicated with the bottom of the refrigerator; the main control box is internally provided with a power switch, a control power switch, a phase sequence protector, an intermediate relay, a time relay, a compressor contactor, a cooling water pump contactor, a gear motor contactor, a thermal relay and a power connection terminal, and in the practical application process, the main control box, the refrigerator, a speed reducer, a compressor and a condenser which are arranged on the upper part of the refrigerator can achieve a stable liquid ice preparation effect by utilizing the bearing platform and the main control box, the refrigerator, and the speed reducer, the compressor and the condenser which are arranged on the bearing platform.

Description

Microcomputer system for fluidized ice making equipment

[ technical field ]

The utility model relates to the technical field of ice making equipment, in particular to a microcomputer system with high control accuracy and high reliability for fluid ice making equipment.

[ background Art ]

The ice maker is a production equipment for producing ice slurry by using salt water or seawater as raw material, is applicable to the fields of fishing, quick cooling and refrigerating of food and the like, and has the advantages of quick cooling speed, easy transportation, no damage to food surface layer, energy saving and the like.

The existing ice machine has the same operation principle, and each main functional component generally has only differences in model, performance and the like, however, the existing ice machine still has more defects in the actual application process, such as low safety of electric control accuracy, inconvenience in carrying, low intelligent degree, inconvenience in control in the actual application process and the like, and restricts better popularization and application of equipment.

Based on this, in order to better promote the practicality and reliability of the apparatus, improvement and improvement of structural parts and electric control parts are required to be performed in a targeted manner.

[ summary of the utility model ]

To overcome the problems of the prior art, namely: the safety of the electric control accuracy is not high, the carrying is not facilitated, the intelligent degree is low, and the like;

the utility model provides a microcomputer system for a fluidized ice making device, which has high control accuracy and high reliability.

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

the microcomputer system comprises a bearing platform, a main control box, a refrigerator, a speed reducer, a compressor and a condenser, wherein the main control box, the refrigerator, the speed reducer, the compressor and the condenser are arranged on the bearing platform; a compressor rack for installing the compressor is erected on the bearing platform; the condenser is positioned at the inner side part of the compressor rack; the ice-making device also comprises a refrigerator arranged close to the refrigerator and an ice-making pump communicated with the bottom of the refrigerator; the main control box is internally provided with a power switch, a control power switch, a phase sequence protector, an intermediate relay, a time relay, a compressor contactor, a cooling water pump contactor, a gear motor contactor, a thermal relay and a power connection terminal; a control panel is arranged outside the main control box; the control panel is provided with a switch button, an operation indicator lamp, a speed reducer overload indicator lamp, a stop button, a function switch, a speed reducer operation indicator lamp, a speed reducer button, a high-voltage protection indicator lamp, a compressor protection indicator lamp, a scram switch, a compressor overload indicator lamp, a low-voltage protection indicator lamp, a power indicator lamp, a cooling water pump overload indicator lamp and a timing shutdown standby start button.

Preferably, the power switch, the control power switch, the phase sequence protector, the intermediate relay and the time relay are arranged in parallel at the upper side part inside the main control box.

Preferably, the compressor contactor, the cooling water pump contactor and the gear motor contactor are arranged in parallel at the middle part inside the main control box.

Preferably, the thermal relay is respectively arranged at the lower side parts of the compressor contactor, the cooling water pump contactor and the speed reducing motor contactor.

Preferably, the power connection terminal is located at the lower side inside the main control box.

Preferably, a temperature sensor for sensing temperature is further arranged in the main control box; and an alarm flash lamp is arranged at the top of the main control box.

Preferably, the top of the refrigerator is provided with an ice discharging bent pipe for discharging ice into the refrigerator.

Preferably, the refrigerator is internally provided with a spiral ice blade for cutting the wall ice layer.

The beneficial effects of solving specific technical problems are as follows:

compared with the prior art, the microcomputer system for the ice making equipment for the fluid ice is characterized in that a bearing platform 11, a main control box 12, a refrigerator 16, a speed reducer 15, a compressor 14 and a condenser 19 which are arranged on the bearing platform 11 are simultaneously arranged, the speed reducer 15, the compressor 14 and the condenser 19 which are arranged on the upper part of the refrigerator 16, a compressor rack 13 for arranging the compressor 14 is erected on the bearing platform 11, the condenser 19 is positioned at the inner side part of the compressor rack 13, the microcomputer system also comprises a refrigerator 17 which is arranged close to the refrigerator 16, and an ice pump 18 which is communicated with the bottom of the refrigerator 17, a power switch 121, a control power switch 122, a phase sequence protector 123, an intermediate relay 124, a time relay 125, a compressor contactor 126, a cooling water pump contactor 127, a speed reducing motor contactor 128, a thermal relay 129 and a power terminal 120 are arranged in the main control box 12, the main control box 12 is externally provided with a control panel, a switch button, an operation indicator lamp, a speed reducer overload indicator lamp, a stop button, a function switch, a speed reducer operation indicator lamp, a speed reducer button, a high-voltage protection indicator lamp, a compressor protection indicator lamp, an emergency stop switch, a compressor overload indicator lamp, a low-voltage protection indicator lamp, a power indicator lamp, a cooling water pump overload indicator lamp and a timing shutdown standby start button are arranged on the control panel, and in the practical application process, the bearing platform 11 and the main control box 12, the refrigerator 16, the speed reducer 15, the compressor 14 and the condenser 19 arranged on the upper portion of the refrigerator 16 can be better utilized to achieve a stable liquid ice preparation effect, and the control precision is high, and the operation reliability is high.

[ description of the drawings ]

Fig. 1 is a schematic view showing an application state structure of a microcomputer system for a fluid ice making apparatus according to the present utility model.

Fig. 2 is a schematic view showing the internal state structure of a main control box in a microcomputer system for a fluid ice making apparatus according to the present utility model.

Detailed description of the preferred embodiments

For the purpose of making the technical solutions and advantages of the present utility model more apparent, the present utility model will be described in further detail below with reference to the accompanying drawings and examples. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

Referring to fig. 1 and 2, a microcomputer system 1 for a fluidized ice making apparatus of the present utility model includes a carrying platform 11, a main control box 12 installed on the carrying platform 11, a refrigerator 16, a decelerator 15 at an upper portion of the refrigerator 16, a compressor 14, and a condenser 19; a compressor rack 13 for installing the compressor 14 is erected on the bearing platform 11; the condenser 19 is positioned at the inner side part of the compressor rack 13; the ice-making device also comprises a refrigerator 17 arranged close to the refrigerator 16 and an ice-making pump 18 communicated with the bottom of the refrigerator 17; the main control box 12 is internally provided with a power switch 121, a control power switch 122, a phase sequence protector 123, an intermediate relay 124, a time relay 125, a compressor contactor 126, a cooling water pump contactor 127, a gear motor contactor 128, a thermal relay 129 and a power connection terminal 120; a control panel is arranged outside the main control box 12; the control panel is provided with a switch button, an operation indicator lamp, a speed reducer overload indicator lamp, a stop button, a function switch, a speed reducer operation indicator lamp, a speed reducer button, a high-voltage protection indicator lamp, a compressor protection indicator lamp, a scram switch, a compressor overload indicator lamp, a low-voltage protection indicator lamp, a power indicator lamp, a cooling water pump overload indicator lamp and a timing shutdown standby start button.

The refrigerator cooling system comprises a bearing platform 11, a main control box 12, a refrigerator 16 and a speed reducer 15, a compressor 14 and a condenser 19 which are arranged on the bearing platform 11, wherein the speed reducer 15, the compressor 14 and the condenser 19 are arranged on the upper portion of the refrigerator 16, the bearing platform 11 is provided with a compressor rack 13 used for arranging the compressor 14, the condenser 19 is positioned on the inner side of the compressor rack 13, the refrigerator cooling system further comprises an ice pump 18 which is close to the refrigerator 17 arranged on the refrigerator 16 and is communicated with the bottom of the refrigerator 17, a power switch 121, a control power switch 122, a phase sequence protector 123, an intermediate relay 124, a time relay 125, a compressor contactor 126, a cooling water pump contactor 127, a speed reducing motor contactor 128, a thermal relay 129 and a power connection terminal 120 are arranged inside the main control box 12, and a control panel is provided with a switch button, an operation indicator lamp, a speed reducer overload indicator lamp, a stop button, a function switch, a speed reducer operation indicator lamp, a speed reducer button, a high-voltage protection indicator lamp, a compressor protection indicator lamp 123, a compressor protection lamp, a phase sequence protector 123, a middle relay 125, a time relay 125, a compressor protection lamp and a power supply terminal 120 are arranged on the main control box 12, and a cooling water pump 11 are arranged on the main control box 12, and the refrigerator cooling system is in the refrigerator cooling system, the system has the actual cooling system, and the refrigerator cooling system has the high-cooling system, and the high-down system has the high-voltage control system, and the control system is stable.

In some other embodiments, the power switch 121, the control power switch 122, the phase sequence protector 123, the intermediate relay 124 and the time relay 125 are arranged in parallel at the upper side position inside the main control box 12; the compressor contactor 126, the cooling water pump contactor 127 and the gear motor contactor 128 are arranged in parallel at the middle part inside the main control box 12; the thermal relay 129 is respectively arranged at the lower side parts of the compressor contactor 126, the cooling water pump contactor 127 and the gear motor contactor 128; the power connection terminal 120 is positioned at the lower side of the inner part of the main control box 12; a temperature sensor for sensing temperature is also arranged in the main control box 12; an alarm flash lamp is arranged at the top of the main control box 12; an ice discharging bent pipe for discharging ice into the refrigerator 17 is arranged at the top of the refrigerator 16; the refrigerator 16 is also internally provided with a spiral ice blade for cutting the wall ice layer.

In the actual application process, a primary water supply mode or a circulating water supply mode can be selected according to actual requirements. The primary water supply is that ice making water is directly conveyed to the refrigerator 16 from a water source, cold water flowing out of the refrigerator 16 is not cooled repeatedly, and ice slurry prepared by the method has low ice content concentration; the cold water in the ice slurry is extracted by circulating water supply and is circularly conveyed to the ice making refrigerator 16 for making ice, and the ice slurry made in the mode has higher ice content concentration. Through the switching of pipeline valve, can realize the switching of ice-making mode and cold water mode. The submersible pump can also be used as a water supply pump, and the submersible pump is wholly immersed in the ice storage tank during working and directly pumps liquid water in the ice storage tank for circulation. The submersible pump can simplify pipeline connection, and is more convenient to install and use.

The beneficial effects of this application are as follows:

compared with the prior art, the microcomputer system 1 for the ice making equipment for fluid ice is characterized in that a bearing platform 11, a main control box 12, a refrigerator 16, a speed reducer 15, a compressor 14 and a condenser 19 which are arranged on the bearing platform 11 are simultaneously arranged, the speed reducer 15, the compressor 14 and the condenser 19 which are arranged on the upper part of the refrigerator 16, a compressor rack 13 for arranging the compressor 14 is arranged on the bearing platform 11, the condenser 19 is arranged at the inner side part of the compressor rack 13, the microcomputer system also comprises a refrigerator 17 which is arranged close to the refrigerator 16, and an ice pump 18 which is communicated with the bottom of the refrigerator 17, a power switch 121, a control power switch 122, a phase sequence protector 123, an intermediate relay 124, a time relay 125, a compressor contactor 126, a cooling water pump contactor 127, a speed reducing motor contactor 128, a thermal relay 129 and a power connection terminal 120 are arranged in the main control box 12, the main control box 12 is externally provided with a control panel, a switch button, an operation indicator lamp, a speed reducer overload indicator lamp, a stop button, a function switch, a speed reducer operation indicator lamp, a speed reducer button, a high-voltage protection indicator lamp, a compressor protection indicator lamp, an emergency stop switch, a compressor overload indicator lamp, a low-voltage protection indicator lamp, a power indicator lamp, a cooling water pump overload indicator lamp and a timing shutdown standby start button are arranged on the control panel, and in the practical application process, the bearing platform 11 and the main control box 12, the refrigerator 16, the speed reducer 15, the compressor 14 and the condenser 19 arranged on the upper portion of the refrigerator 16 can be better utilized to achieve a stable liquid ice preparation effect, and the control precision is high, and the operation reliability is high.

The embodiments of the present utility model described above do not limit the scope of the present utility model. Any modifications, equivalent substitutions and improvements made within the spirit and principles of the present utility model should be included in the scope of the present utility model as set forth in the appended claims.

Claims (8)

1. A microcomputer system for a fluidized ice making apparatus, characterized by: the device comprises a bearing platform, a main control box, a refrigerator, a speed reducer, a compressor and a condenser, wherein the main control box, the refrigerator, the speed reducer, the compressor and the condenser are arranged on the bearing platform; a compressor rack for installing the compressor is erected on the bearing platform; the condenser is positioned at the inner side part of the compressor rack; the ice-making device also comprises a refrigerator arranged close to the refrigerator and an ice-making pump communicated with the bottom of the refrigerator; the main control box is internally provided with a power switch, a control power switch, a phase sequence protector, an intermediate relay, a time relay, a compressor contactor, a cooling water pump contactor, a gear motor contactor, a thermal relay and a power connection terminal; a control panel is arranged outside the main control box; the control panel is provided with a switch button, an operation indicator lamp, a speed reducer overload indicator lamp, a stop button, a function switch, a speed reducer operation indicator lamp, a speed reducer button, a high-voltage protection indicator lamp, a compressor protection indicator lamp, a scram switch, a compressor overload indicator lamp, a low-voltage protection indicator lamp, a power indicator lamp, a cooling water pump overload indicator lamp and a timing shutdown standby start button.

2. A microcomputer system for a fluid ice making apparatus as recited in claim 1, wherein: the power switch, the control power switch, the phase sequence protector, the intermediate relay and the time relay are arranged in parallel at the upper side part inside the main control box.

3. A microcomputer system for a fluid ice making apparatus as recited in claim 1, wherein: the compressor contactor, the cooling water pump contactor and the gear motor contactor are arranged in parallel in the middle part inside the main control box.

4. A microcomputer system for a fluid ice making apparatus as recited in claim 3, wherein: the thermal relay is respectively arranged at the lower side parts of the compressor contactor, the cooling water pump contactor and the speed reducing motor contactor.

5. A microcomputer system for a fluid ice making apparatus as recited in claim 1, wherein: the power connection terminal is positioned at the lower side inside the main control box.

6. A microcomputer system for a fluid ice making apparatus according to any one of claims 1 to 5, wherein: a temperature sensor for sensing the temperature is also arranged in the main control box; and an alarm flash lamp is arranged at the top of the main control box.

7. A microcomputer system for a fluid ice making apparatus as recited in claim 1, wherein: the top of the refrigerator is provided with an ice discharging bent pipe for discharging ice into the refrigerator.

8. A microcomputer system for a fluid ice making apparatus as recited in claim 1, wherein: the refrigerator is characterized in that a spiral ice blade for cutting the wall ice layer is further arranged in the refrigerator.

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