CN212140375U - Double-heat-source type air-energy heating dish washing machine - Google Patents

Abstract

The utility model discloses a double-heat-source air-energy heating dish washing machine, which comprises a frame, a transmission mechanism is arranged on the frame, a hood is arranged on the frame, an air-energy-saving system is arranged in the hood, and a plurality of separated mutually communicated working chambers are arranged in the hood, the air-energy-saving system comprises an air-energy heat-collecting component, an air-energy host machine and an air-energy heating component, the air-energy host machine and at least two groups of air-energy heating components are all positioned in the space below the frame, the utility model adopts a set of air-energy compression system, a working closed-loop mode consisting of two sets of air-energy heating component modes, which can not only meet the heat supply of a rinsing chamber, but also can supply heat to a cleaning chamber, the two sets of components can also work independently, no logic influence is generated between each other, and the power consumption is only one fourth of, and two sets of air energy heat collection component modes are adopted, so that the waste heat is recycled to the maximum extent, the energy is saved, the consumption is reduced, and the environment is protected.

Description

Double-heat-source type air-energy heating dish washing machine

Technical Field

The utility model relates to a commercial dish washer technical field especially relates to a two heat source formula air can heat dish washer.

Background

The dish washer is used to automatically clean tableware such as dish, chopsticks, dish, knife and fork. Fully automatic dishwashers on the market can be divided into two categories, domestic and commercial.

The commercial dish-washing machine can be divided into a cabinet type, a cover type, a basket transmission type, a belt transmission type and an ultrasonic 5 class according to the structure, thereby reducing the labor intensity of cooking personnel in restaurants, hotels and canteens of institutions, improving the working efficiency and promoting the cleanness and the sanitation. Traditional industry dish washer needs a large amount of hot water circulation at the in-process that washes dishes, and the mode of electric heating is mainly adopted to the source of present hot water, needs powerful heater, leads to the charges of electricity high, and some electric load can not install excessively low place, has limited the application scope of dish washer, and in addition, the heat that takes away when the heat that sends and washing water discharge in the course of the work can't all be utilized by, causes the waste on the energy.

SUMMERY OF THE UTILITY MODEL

The utility model discloses it is not enough to prior art, it is lower to provide an energy consumption, and service environment is wider to furthest retrieves thermal double heat source formula air and can heat dish washer.

In order to solve the technical problem, the utility model discloses a following technical scheme can solve: double heat source formula air can heat dish washer, including the frame laid transport mechanism in the frame, the frame upper shield is equipped with the aircraft bonnet, be provided with air in the aircraft bonnet and can economizer system to and the working chamber of a plurality of intercommunications each other that are separated, air can economizer system include air can thermal-arrest subassembly, air can host computer, air can heating element, air can host computer and at least arranged two sets ofly air can heating element all is located in the space of frame below.

In the technical scheme, the working cavity comprises a cleaning cavity, a rinsing cavity, a drying cavity and a gas collecting cavity.

In the above technical scheme, the air energy heating assembly comprises a first air energy heating assembly and a second air energy heating assembly.

In the above technical scheme, the first air energy heating assembly is arranged in the rack below the cleaning cavity and comprises a cleaning air energy heating pipe located in the cleaning water tank.

In the above technical scheme, the second air energy heating assembly is arranged in the rack below the drying cavity and comprises a rinsing air energy heating pipe located in the hot water tank.

In the technical scheme, the gas collection chamber includes first collection steam pocket, second collection steam pocket and third collection steam pocket, first collection steam pocket be located wash the front end in chamber, second collection steam pocket set up in the rear end in stoving chamber, third collection steam pocket locate wash the chamber rinse the chamber and the top in stoving chamber to make through the intake duct first collection steam pocket second collection steam pocket with third collection steam pocket UNICOM, the intake duct front end be provided with external UNICOM's air inlet.

In the technical scheme, the air inlet passage comprises an air inlet passage and an air outlet passage, the air inlet passage is of a three-way structure and is communicated with the external environment, the first steam collecting cavity and the third steam collecting cavity, and the air outlet passage is communicated with the second steam collecting cavity and the third steam collecting cavity.

Among the above-mentioned technical scheme, the air can the thermal-arrest subassembly include the first thermal-arrest subassembly of air ability and the second thermal-arrest subassembly of air ability.

In the above technical scheme, the first heat collecting assembly of air energy comprises a fan and an air energy heat collector, wherein the fan and the air energy heat collector are arranged at the top of the third steam collecting cavity.

In the above technical scheme, the air energy second heat collecting assembly includes a waste water end heat exchange box and an air energy heat collecting plate located in the waste water end heat exchange box, the waste water end heat exchange box and the air energy heat collecting plate are arranged in the frame below the cleaning cavity, and the waste water end heat exchange box is communicated with the cleaning water outlet.

Compared with the prior art, the method has the following beneficial effects: the utility model discloses an one set of air can compression system, the work closed loop mode that two sets of air can the heating element mode is constituteed, not only can satisfy the heat supply in rinsing chamber, also can carry out the heat supply to wasing the chamber simultaneously, two sets of subassemblies also can the autonomous working, do not produce logical influence each other, and power consumption only is the fourth of ordinary electrothermal tube heating energy consumption, adopt two sets of air can thermal-arrest subassembly modes, furthest carries out recycle to the waste heat, energy saving and consumption reduction, more environmental protection.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

Referring to fig. 1, the double-heat-source air-energy-heating dish washing machine comprises a rack 1, a conveying mechanism is arranged on the rack 1, a hood 11 is arranged on the rack 1, an air energy saving system is arranged in the hood 11, and a plurality of separated working chambers which are communicated with each other are arranged, the air energy saving system comprises an air energy heat collecting assembly, an air energy host machine 33 and an air energy heating assembly, and the air energy host machine 33 and at least two groups of air energy heating assemblies are arranged in a space below the rack 1.

The conveying mechanism comprises a conveying guide rail 21, a conveying rack, a dish fixing frame 22 and a conveying power mechanism 23, the conveying rack is arranged on the upper surface of the rack 1 and penetrates through the working cavity, the conveying guide rail 21 is arranged on the conveying rack, and the dish fixing frame 22 is arranged on the conveying guide rail 21.

The working chamber includes washing chamber 12, rinsing chamber 13, stoving chamber 14 and gas collection chamber, and air can heating element include first air can heating element and second air can heating element, and first air can heating element sets up in frame 1 of washing chamber 12 below, including being located the washing air of washing water tank 121 can heating pipe 341, and second air can heating element sets up in frame 1 of stoving chamber 14 below, including being located the rinsing air of hot-water tank 131 can heating pipe 344.

The gas collecting cavity includes first steam collecting cavity 151, second steam collecting cavity 152 and third steam collecting cavity 153, first steam collecting cavity 151 is located the front end that washs chamber 12, second steam collecting cavity 152 sets up in the rear end of stoving chamber 14, washing chamber 12 is located to third steam collecting cavity 153, the top in rinsing chamber 13 and stoving chamber 14, and make first steam collecting cavity through the intake duct, second steam collecting cavity and third steam collecting cavity UNICOM, the intake duct front end is provided with the air inlet with external UNICOM, the intake duct includes preceding air flue 41 and back air flue 42, preceding air flue 41 is tee bend structure, the external environment of UNICOM simultaneously, first steam collecting cavity 151 and third steam collecting cavity 153, back air flue 42 UNICOM is between second steam collecting cavity 152 and third steam collecting cavity 153.

The air energy heat collection component comprises an air energy first heat collection component and an air energy second heat collection component, the air energy first heat collection component comprises a fan 311 and an air energy heat collector 312, the fan 311 and the air energy heat collector 312 are both arranged at the top of the third steam collection cavity 153, the air energy second heat collection component comprises a waste water end heat exchange box 313 and an air energy heat collection plate 314 located in the waste water end heat exchange box 313, the waste water end heat exchange box 313 and the air energy heat collection plate 314 are arranged in the rack 1 below the cleaning cavity 12, and the waste water end heat exchange box 313 is communicated with the cleaning water tank 121.

The dishwasher in the technical scheme is realized as follows:

the water tank and the water inlet system work: the water source is controlled to be filled into the hot water tank 131 and the cleaning water tank 121 respectively through two water inlet electromagnetic valves arranged at the water inlet pipe, and the water level is controlled by a hot water tank liquid level sensor arranged in the hot water tank 131 and a cleaning tank liquid level sensor arranged in the cleaning water tank 121 respectively.

The air energy heating system works: the utility model adopts an air energy host machine 33 for the first air energy heating component and the second air energy heating component of the dish washer, and the two components can also work independently without logic influence; the number of the heat sources of the air energy is two, namely a first heat collection component at the air end and a second heat collection component at the waste water end, and the first heat collection component and the second heat collection component absorb heat from the air and the waste water respectively.

Dish delivery system: the bowls and dishes are placed on the conveying guide rail 21, the conveying guide rail 21 can adopt a conveying belt structure, other structures can also be adopted, the conveying guide rail can be freely selected according to the use environment, the conveying power mechanism 23 is driven, and the bowls and dishes are conveyed into the dish washing machine for washing through the left inlet.

Dish washing system: the washing circulation pump 122 located at one side of the washing water tank 121 pumps the water in the washing water tank 121 to continuously wash dishes passing through the washing chamber 12 in a large flow and large pressure manner through the washing water jet, so as to clean up stains on the dishes, and since the washing is assisted by a certain temperature, the washing air energy heating pipe 341 is required to heat the water for washing the washing water tank 121, and if the heating temperature is not enough, the washing water auxiliary heating pipe 123 located at one side of the washing water tank 121 can assist in heating. The steam emitted from the cleaning chamber 12 is collected by the first steam collecting chamber 151 and then absorbed by the air energy heat collector 312 for recycling, thereby forming a heat closed loop.

Dish rinsing system: the rinsing and the disinfection of the dishwasher are integrally completed, so that the temperature of the rinsing water needs to reach more than 81 ℃. The rinsing air energy heating pipe 344 in the hot water tank 131 heats water to 70-80 ℃, the water is conveyed into the rinsing heat preservation auxiliary heating tank 133 from the rinsing water supply port of the hot water tank 131 by the rinsing water pump 132 positioned below the rinsing cavity 13, the heating pipe 1331 in the auxiliary heating tank heats the water to above 82 ℃ and preserves the temperature, then the water is sprayed out from the rinsing spraying port in the rinsing cavity 13 to rinse and disinfect dishes, the rinsed hot water flows into the cleaning cavity 12 from the rinsing cavity 13, and then is discharged to the waste water end heat exchange tank 313 from the cleaning water outlet of the cleaning cavity 12 to exchange heat and then is discharged.

Dish drying system: the rinsed dishes are conveyed out of the dish washing machine after passing through the drying cavity 14, and the whole dish washing process is completed.

Wherein, all work at whole in-process air ability thermal-arrest subassembly, its principle is: the fan 311 sucks the hot air and the dissipated steam in the first steam collecting cavity 151 and the second steam collecting cavity 152 of the dishwasher chamber through the air inlet channel, and the damp and hot air passes through the air energy heat collector 312, and the heat is absorbed by the low-temperature refrigerant in the pipeline of the air energy heat collector 312 through the heat collecting fins, is conveyed to the air energy host computer 33, and is generated into the high-temperature refrigerant through the compression effect.

The high-temperature wastewater flowing out of the cleaning water tank 121, which has a temperature of about 55 ℃, flows through the wastewater-side heat exchange tank 313, and the heat is absorbed by the low-temperature refrigerant in the air energy heat collection plate 314 located in the wastewater-side heat exchange tank 313, and flows into the air energy main unit 33 through the pipeline, and is converted into the high-temperature refrigerant through the compression action of the air energy main unit 33; the waste water is discharged through the water outlet after absorbing heat.

The high-temperature refrigerant is controlled by an electromagnetic valve arranged in the system and is conveyed to the cleaning air energy heating pipe 341 through a copper pipe to heat the cleaning water in the cleaning water tank 121. The heating temperature in the cleaning water tank 121 is controlled by a temperature sensor, and the setting of the relevant temperature can be adjusted, and the temperature of the high-temperature refrigerant after heat exchange is reduced and circulated to the air energy heat collector 312 and the air energy heat collecting plate 314.

The high temperature refrigerant is controlled by a second solenoid valve arranged in the system and is conveyed to the rinsing air energy heating pipe 344 through a copper pipe to heat water in the hot water tank 131. The heating temperature in the hot water tank 131 is controlled by the temperature sensor, the setting of the relevant temperature can be adjusted, and the temperature of the high-temperature refrigerant after heat exchange is reduced and circulated to the air energy heat collector 312.

The work of the two sets of heat source systems is completed in a closed loop.

The energy consumption of the air energy heating system is only one fourth of that of a common electric heating pipe, so that three fourths of heating power can be saved, heat emitted in the working process can be absorbed to the maximum extent, energy is saved, consumption is reduced, and the air energy heating system has a good market prospect.

The protection scope of the present invention includes but is not limited to the above embodiments, the protection scope of the present invention is subject to the claims, and any replacement, deformation, and improvement that can be easily conceived by those skilled in the art made by the present technology all fall into the protection scope of the present invention.

Claims (10)

1. Double heat source formula air can heat dish washer, including frame (1), its characterized in that laid transport mechanism on frame (1), frame (1) upper shield is equipped with aircraft bonnet (11), be provided with air can economizer system in aircraft bonnet (11) to and the working chamber of a plurality of intercommunications each other separated, air can economizer system include air can thermal-arrest subassembly, air can host computer (33), air can heating element, air can host computer (33) and arranged at least two sets of air can heating element all is located in the space of frame (1) below.

2. The dual heat source air-heatable dishwasher of claim 1, characterized in that the working chambers comprise a washing chamber (12), a rinsing chamber (13), a drying chamber (14) and a gas collection chamber.

3. The dual heat source air-heated dishwasher of claim 2, wherein the air-heated component comprises a first air-heated component and a second air-heated component.

4. A dual heat source air-heatable dishwasher according to claim 3, characterized in that the first air-heatable component is arranged in the housing (1) below the washing chamber (12), comprising a washing air-heatable pipe (341) in a washing water tank (121).

5. A dual heat source air-heatable dishwasher according to claim 3, characterized in that the second air-heatable component is arranged in the rack (1) below the drying chamber (14), comprising rinsing air-heatable pipes (344) in a hot water tank (131).

6. The dual-heat-source air-heated dishwasher of claim 2, wherein the air collection chamber comprises a first air collection chamber (151), a second air collection chamber (152) and a third air collection chamber (153), the first air collection chamber (151) is located at the front end of the cleaning chamber (12), the second air collection chamber (152) is located at the rear end of the drying chamber (14), the third air collection chamber (153) is located at the top of the cleaning chamber (12), the rinsing chamber (13) and the drying chamber (14), the first air collection chamber, the second air collection chamber and the third air collection chamber are communicated through an air inlet, and the front end of the air inlet is provided with an air inlet communicated with the outside.

7. The dual heat source type air-heatable dishwasher of claim 6, wherein the air intake duct comprises a front air duct (41) and a rear air duct (42), the front air duct (41) is of a three-way structure and is communicated with the external environment, the first steam collecting chamber (151) and the third steam collecting chamber (153), and the rear air duct (42) is communicated between the second steam collecting chamber (152) and the third steam collecting chamber (153).

8. The dual heat source air heated dishwasher of claim 6, wherein the air energy heat collecting assembly comprises an air energy first heat collecting assembly and an air energy second heat collecting assembly.

9. The dual heat source air-heated dishwasher of claim 8, characterized in that the air-energy first heat collecting assembly comprises a fan (311), an air-energy heat collector (312), both the fan (311) and the air-energy heat collector (312) being arranged on top of the third steam collecting chamber (153).

10. The dual heat source air-heated dishwasher of claim 8, characterized in that the air-energy second heat collecting assembly comprises a waste-side heat exchange tank (313) and an air-energy heat collecting plate (314) located in the waste-side heat exchange tank (313), the waste-side heat exchange tank (313) and the air-energy heat collecting plate (314) are disposed in the housing (1) below the washing chamber (12), and the waste-side heat exchange tank (313) is in communication with a washing drain.

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