CN201166494Y

CN201166494Y - High-efficiency and energy-saving steaming machine

Info

Publication number: CN201166494Y
Application number: CNU2008200077249U
Authority: CN
Inventors: 凌建军; 黄鹂
Original assignee: Individual
Current assignee: Individual
Priority date: 2008-02-28
Filing date: 2008-02-28
Publication date: 2008-12-17
Anticipated expiration: 2018-02-28

Abstract

The utility model discloses a highly effective energy-saving object steaming machine, which comprises a boiling insulated cylinder assembly, a condensing insulated cylinder assembly, a multi-source heat pump assembly, a water receiving and replenishing tank, a frequency changer and a program controller, wherein the highly effective energy-saving object steaming machine skillfully utilizes a heat collecting coiler of a multi-source heat pump to absorb heat of deicing fluid in a liquid storage tank, to absorb the heat in the air, to absorb the heat of high temperature steam to heat, thereby realizing that the electricity is saved by more than 80%, steam condensed water can be automatically replenished into the boiling insulated cylinder, thereby realizing highly effective water conservation, since the deicing fluid is installed in the liquid storage tank, heat preparation can be realized in cold seasons, the highly effective energy-saving object steaming machine can reduce the high temperature steam to overflow into the air, thereby reducing the heat pollution to the environment.

Description

High-efficiency energy-saving steamer

Affiliated technical field

The utility model relates to steamer, be particularly related to high-efficiency energy-saving steamer, it can be a meal braizing machine, steamed wheaten foods thing machine, the food service industry precooker, steam the dish machine, the steamed meat machine, the Steamed fish machine, steam the seafood machine, the steamed sweet bun machine, steam bread producing machine, machine steams stuffed bun, the steamed dumpling handset, steam the some scheming, steam the liquor raw material machine, steam fodder machine, evaporate worker's raw material machine, steam the organic matter machine, steam the plant machine, the paper material precooker, steam the timber machine, steam the bamboo machine, steam the reed machine, steam the straw machine, steam the rattan machine, the sugaring precooker, the table-ware disinfection precooker, the sterilization precooker, the decolouring precooker, steam material distributing machine, steam cloth apparatus, steam leather machine, evaporate fine machine, the feather precooker, steam the inorganic matter machine, the industry precooker, in the agricultural precooker any one.

Background technology

The whole world more than 60 hundred million populations need be eaten up 3,000,000,000 tons of foods every year, and 3,000,000,000 tons of foods of boiling generally adopt electricity directly to heat or with the natural gas heating or with the coal heating, consume lot of energy.Need power consumption 0.3 degree to calculate by per kilogram food, then cooking annual power consumption total amount in the whole world is 9,000 hundred million degree, needs 0.36 kilogram of calculating of consumption coal by every degree electricity, is equivalent to consume 3.24 hundred million tons in coal, will arrange 5.508 hundred million tons of carbon dioxide to the earth.If can economize on electricity 80%, 7,200 hundred million degree that then can economize on electricity can be saved 2.592 hundred million tons of coals, but 4.4064 hundred million tons of reducing emission of carbon dioxide.

Need to carry out boiling in producing processes such as wine, sugar, paper, industrial chemicals, feed, cloth, leather, chemical fibre, wig, bamboo product, will consume lot of energy in digestion process, the steam that boiling produces has caused thermal pollution to environment.If can economize on electricity, then can save a large amount of coals and reduce discharging a large amount of carbon dioxide.

Summary of the invention

Meal braizing machine consumes energy especially at present, per kilogram grain power consumption 0.3 degree, in addition more.The disclosed high-efficiency energy-saving steamer of the utility model utilize dexterously the heat absorption coil pipe of Multisource heat pump absorb the anti-icing fluid in the liquid reserve tank heat, absorb airborne heat, the heat that absorbs high-temperature steam heats, thereby realizes energy-efficient.

The utility model discloses high-efficiency energy-saving steamer, it comprises cooking and heat-preservation tube assembly, condensation heat-preservation cylinder assembly, Multisource heat pump assembly, it is characterized in that the cooking and heat-preservation tube escape pipe of described cooking and heat-preservation tube assembly links to each other with the condensation heat-preservation cylinder air inlet pipe of condensation heat-preservation cylinder assembly; The condensation heat-preservation cylinder discharging tube of described condensation heat-preservation cylinder assembly is connected with the cooking and heat-preservation tube filling pipe of cooking and heat-preservation tube assembly; The radiator coil tube of described Multisource heat pump assembly is installed in the cooking and heat-preservation tube inner casing of cooking and heat-preservation tube assembly; The 3rd heat absorption coil pipe of described Multisource heat pump assembly is installed in the condensation heat-preservation cylinder inner casing of condensation heat-preservation cylinder assembly.

Described high-efficiency energy-saving steamer also comprises receives water water supply tank, frequency converter, cyclelog, liquid-level switch; Described receipts water water supply tank is installed on the condensation heat-preservation cylinder discharging tube or on the cooking and heat-preservation tube filling pipe or between condensation heat-preservation cylinder discharging tube and the cooking and heat-preservation tube filling pipe; Described cyclelog links to each other with compressor, frequency converter, liquid-level switch; Described liquid-level switch is installed on the cooking and heat-preservation tube assembly.

Described cooking and heat-preservation tube assembly comprises cooking and heat-preservation tube shell, cooking and heat-preservation tube thermal insulation layer, cooking and heat-preservation tube inner casing, cooking and heat-preservation tube venthole, cooking and heat-preservation tube escape pipe, cooking and heat-preservation tube discharging tube, cooking and heat-preservation tube tapping valve, cooking and heat-preservation tube filling pipe, ball float water compensating valve; Described cooking and heat-preservation tube thermal insulation layer is installed between cooking and heat-preservation tube shell and the cooking and heat-preservation tube inner casing; Described cooking and heat-preservation tube venthole runs through cooking and heat-preservation tube shell, cooking and heat-preservation tube thermal insulation layer and cooking and heat-preservation tube inner casing; Described cooking and heat-preservation tube escape pipe links to each other with cooking and heat-preservation tube venthole; Described cooking and heat-preservation tube discharging tube passes cooking and heat-preservation tube shell, cooking and heat-preservation tube thermal insulation layer and cooking and heat-preservation tube inner casing successively; Described cooking and heat-preservation tube filling pipe passes cooking and heat-preservation tube shell, cooking and heat-preservation tube thermal insulation layer and cooking and heat-preservation tube inner casing successively, and links to each other with the ball float water compensating valve.

Described condensation heat-preservation cylinder assembly comprises condensation heat-preservation cylinder shell, condensation heat-preservation cylinder thermal insulation layer, condensation heat-preservation cylinder inner casing, condensation heat-preservation cylinder air admission hole, condensation heat-preservation cylinder air inlet pipe, condensation heat-preservation cylinder discharging tube; Described condensation heat-preservation cylinder thermal insulation layer is installed between condensation heat-preservation cylinder shell and the condensation heat-preservation cylinder inner casing, and described condensation heat-preservation cylinder air admission hole runs through condensation heat-preservation cylinder shell, condensation heat-preservation cylinder thermal insulation layer and condensation heat-preservation cylinder inner casing; Described condensation heat-preservation cylinder air inlet pipe links to each other with condensation heat-preservation cylinder air admission hole; Described condensation heat-preservation cylinder discharging tube passes condensation heat-preservation cylinder shell, condensation heat-preservation cylinder thermal insulation layer and condensation heat-preservation cylinder inner casing successively.

Described Multisource heat pump assembly comprises compressor, first high-voltage tube, radiator coil tube, second high-voltage tube, capillary-compensated valve, the 3rd high-voltage tube, the first heat absorption coil pipe, liquid reserve tank, heat exchanger fin, the 4th high-voltage tube, the second heat absorption coil pipe, the 5th high-voltage tube, the 3rd heat absorption coil pipe, the 6th high-voltage tube, anti-icing fluid, four-way change-over valve; One end of described first high-voltage tube links to each other with the outlet of compressor, and the other end links to each other with radiator coil tube; Described second high-voltage tube, one end links to each other with radiator coil tube, and the other end links to each other with the capillary-compensated valve; The described first heat absorption coil pipe is installed in the liquid reserve tank, and the one end links to each other with the 3rd high-voltage tube, and the other end links to each other with the 4th high-voltage tube; The described second heat absorption coil pipe two ends link to each other with the 4th high-voltage tube, the 5th high-voltage tube respectively; The two ends of described the 3rd heat absorption coil pipe link to each other with the 5th high-voltage tube, the 6th high-voltage tube respectively; Described the 6th high-voltage tube one end links to each other with the 3rd heat absorption coil pipe, and the other end links to each other with compressor inlet tube; In the described liquid reserve tank anti-icing fluid is housed; Described heat exchanger fin is installed on the liquid reserve tank; Described radiator coil tube is installed in the cooking and heat-preservation tube inner casing; Described four-way change-over valve is connected with compressor outlet pipe, compressor inlet tube, first high-voltage tube, the 6th high-voltage tube respectively.

The beneficial effect of the disclosed high-efficiency energy-saving steamer of the utility model is as follows:

1) utilize dexterously the heat absorption coil pipe of Multisource heat pump absorb the anti-icing fluid in the liquid reserve tank heat, absorb airborne heat, the heat that absorbs high-temperature steam heats, thereby realizes energy-efficient.

2) do not worry occurring the phenomenon of dryouting in digestion process, the steam condensate (SC) that produces in the digestion process can add in the cooking and heat-preservation tube automatically; If the liquid level in the cooking and heat-preservation tube is enough high, it is collected that these steam condensate (SC)s will be received the water water supply tank.

3) can cool off some cooking material fast, during as the boiling liquor raw material, just can start the refrigeration key, cooking material is lowered the temperature rapidly, can reduce labour intensity greatly, can save the production time.Temperature that it should be noted that the anti-icing fluid in the liquid reserve tank of digestion process end back is very low, and this moment, refrigeration can improve refrigerating capacity greatly immediately.

4) can make some cooking material rapid crystallization, during as the boiling syrup, just can start the refrigeration key, make rapidly cooling and crystallization can be saved the production time of cooking material.Temperature that it should be noted that the anti-icing fluid in the liquid reserve tank of digestion process end back equally is very low, and this moment, refrigeration can improve refrigerating capacity greatly immediately.

5) be anti-icing fluid owing to what adorn in the liquid reserve tank, so can realize heating in cold season.

6) since in digestion process liquid reserve tank and second the heat absorption coil pipe will absorb airborne heat, can avoid the workplace temperature too high, thereby improve workman's working environment.

7) it is excessive in air to reduce high-temperature steam, can keep the working environment of workplace drying.

8) can reduce thermal pollution to environment.

Description of drawings

Fig. 1 is the schematic diagram of the utility model high-efficiency energy-saving steamer.

Fig. 2 is the second embodiment boiling schematic diagram of the utility model high-efficiency energy-saving steamer.

Fig. 3 is second embodiment cooling schematic diagram of the utility model high-efficiency energy-saving steamer.

Wherein Reference numeral is as follows:

Cooking and heat-preservation tube shell 1, cooking and heat-preservation tube thermal insulation layer 2, cooking and heat-preservation tube inner casing 3, cooking and heat-preservation tube venthole 4, cooking and heat-preservation tube escape pipe 5, condensation heat-preservation cylinder air inlet pipe 6, condensation heat-preservation cylinder air admission hole 7, condensation heat-preservation cylinder shell 8, condensation heat-preservation cylinder thermal insulation layer 9, condensation heat-preservation cylinder inner casing 10, condensation heat-preservation cylinder discharging tube 11, receive water water supply tank 12, cooking and heat-preservation tube filling pipe 13, ball float water compensating valve 14, compressor 15, first high-voltage tube 16, radiator coil tube 17, second high-voltage tube 18, capillary-compensated valve 19, the 3rd high-voltage tube 20, the first heat absorption coil pipe 21, liquid reserve tank 22, heat exchanger fin 23, the 4th high-voltage tube 24, the second heat absorption coil pipe 25, the 5th high-voltage tube 26, the 3rd heat absorption coil pipe 27, the 6th high-voltage tube 28, cooking and heat-preservation tube discharging tube 29, cooking and heat-preservation tube tapping valve 30, ventilative dividing plate 31, liquid-level switch 32, frequency converter 33, four-way change-over valve 34, cooled exhaust pipe 35, coolant exhaust valve 36, cooling, air discharging fan 37, water compensating valve 38, cyclelog (not marking among the figure).

The specific embodiment

Below in conjunction with accompanying drawing the specific embodiment of the present utility model is described in detail.

First embodiment

Fig. 1 is the principle schematic of the utility model high-efficiency energy-saving steamer.

As shown in Figure 1, the utility model high-efficiency energy-saving steamer, it comprises cooking and heat-preservation tube assembly, condensation heat-preservation cylinder assembly, condensate liquid collection assembly, Multisource heat pump assembly, receives water water supply tank 12, liquid-level switch 32, frequency converter 33, cyclelog (not marking among the figure).

Described cooking and heat-preservation tube assembly comprises cooking and heat-preservation tube shell 1, cooking and heat-preservation tube thermal insulation layer 2, cooking and heat-preservation tube inner casing 3, cooking and heat-preservation tube venthole 4, cooking and heat-preservation tube escape pipe 5, cooking and heat-preservation tube discharging tube 29, cooking and heat-preservation tube tapping valve 30, cooking and heat-preservation tube filling pipe 13, ball float water compensating valve 14; Described cooking and heat-preservation tube thermal insulation layer 2 is installed between cooking and heat-preservation tube shell 1 and the cooking and heat-preservation tube inner casing 3; Described cooking and heat-preservation tube venthole 4 runs through cooking and heat-preservation tube shell 1, cooking and heat-preservation tube thermal insulation layer 2 and cooking and heat-preservation tube inner casing 3; Described cooking and heat-preservation tube escape pipe 5 links to each other with cooking and heat-preservation tube venthole 4; Described cooking and heat-preservation tube discharging tube 29 passes cooking and heat-preservation tube shell 1, cooking and heat-preservation tube thermal insulation layer 2 and cooking and heat-preservation tube inner casing 3 successively; Described cooking and heat-preservation tube filling pipe 13 passes cooking and heat-preservation tube shell 1, cooking and heat-preservation tube thermal insulation layer 2 and cooking and heat-preservation tube inner casing 3 successively, and links to each other with ball float water compensating valve 14.

Described condensation heat-preservation cylinder assembly comprises condensation heat-preservation cylinder shell 8, condensation heat-preservation cylinder thermal insulation layer 9, condensation heat-preservation cylinder inner casing 10, condensation heat-preservation cylinder air inlet pipe 6, condensation heat-preservation cylinder air admission hole 7, condensation heat-preservation cylinder discharging tube 11; Described condensation heat-preservation cylinder thermal insulation layer 9 is installed between condensation heat-preservation cylinder shell 8 and the condensation heat-preservation cylinder inner casing 10; Described condensation heat-preservation cylinder air admission hole 7 runs through condensation heat-preservation cylinder shell 8, condensation heat-preservation cylinder thermal insulation layer 9 and condensation heat-preservation cylinder inner casing 10; Described condensation heat-preservation cylinder air inlet pipe 6 links to each other with condensation heat-preservation cylinder air admission hole 7; Described condensation heat-preservation cylinder discharging tube 11 passes condensation heat-preservation cylinder shell 8, condensation heat-preservation cylinder thermal insulation layer 9 and condensation heat-preservation cylinder inner casing 10 successively.

Described Multisource heat pump assembly comprises compressor 15, first high-voltage tube 16, radiator coil tube 17, second high-voltage tube 18, capillary-compensated valve 19, the 3rd high-voltage tube 20, the first heat absorption coil pipe 21, liquid reserve tank 22, heat exchanger fin 23, the 4th high-voltage tube 24, the second heat absorption coil pipe 25, the 5th high-voltage tube 26, the 3rd heat absorption coil pipe 27, the 6th high-voltage tube 28, anti-icing fluid, four-way change-over valve 34; One end of described first high-voltage tube 16 links to each other with the outlet of compressor 15, and the other end links to each other with radiator coil tube 17; Described second high-voltage tube, 18 1 ends link to each other with radiator coil tube 17, and the other end links to each other with capillary-compensated valve 19; The described first heat absorption coil pipe 21 is installed in the liquid reserve tank 22, and the one end links to each other with the 3rd high-voltage tube 20, and the other end links to each other with the 4th high-voltage tube 24; The described second heat absorption coil pipe 25 two ends link to each other with the 4th high-voltage tube 24, the 5th high-voltage tube 26 respectively; The two ends of described the 3rd heat absorption coil pipe 27 link to each other with the 5th high-voltage tube 26, the 6th high-voltage tube 28 respectively; Described the 6th high-voltage tube 28 1 ends link to each other with the 3rd heat absorption coil pipe 27, and the other end links to each other with the inlet tube of compressor 15; In the described liquid reserve tank 22 anti-icing fluid is housed; Described heat exchanger fin 23 is installed on the liquid reserve tank 22; Described radiator coil tube 17 is installed in the cooking and heat-preservation tube inner casing 3.

Described receipts water water supply tank 12 is installed between condensation heat-preservation cylinder discharging tube 11 and the cooking and heat-preservation tube filling pipe 13; Described cyclelog links to each other with compressor 15, frequency converter 33, liquid-level switch 32; Described liquid-level switch 32 is installed on the cooking and heat-preservation tube assembly.

Is following surface analysis high-efficiency energy-saving steamer how to realize energy-efficient boiling?

At first treating that the boiling object is put on the ventilative dividing plate 31, then by receiving water water supply tank 12 to 3 moisturizings of cooking and heat-preservation tube inner casing, when water level reaches desired location, ball float water compensating valve 14 will be closed, when liquid level reduces once more, ball float water compensating valve 14 will be opened, and allow water enter in the cooking and heat-preservation tube inner casing 3, can guarantee that like this liquid level in the cooking and heat-preservation tube inner casing 3 is setting value; Start-up routine controller (not marking among the figure) afterwards, the compressor 15 of Multisource heat pump assembly is started working, high-temperature high-pressure refrigerant will flow to the radiator coil tube 17 that is installed in the cooking and heat-preservation tube inner casing 3 by first high-voltage tube 16, this moment, radiator coil tube 17 was with the water in the hot digestion heat-preservation cylinder inner casing 3, rising along with temperature, water will be converted into steam, high-temperature steam is treated the boiling object with heating, part steam will condense into water this moment, and part steam will enter in the condensation heat-preservation cylinder inner casing 10 through cooking and heat-preservation tube escape pipe 5, condensation heat-preservation cylinder air inlet pipe 6; Cold-producing medium after the cooling will enter capillary-compensated valve 19 through second high-voltage tube 18, under the effect of capillary-compensated valve 19, the pressure and temperature of cold-producing medium will sharply descend, cold-producing medium after the decrease temperature and pressure enters the first heat absorption coil pipe 21 through the 3rd high-voltage tube 20, heat absorption coil pipe 21 will absorb the heat of the anti-icing fluid in the liquid reserve tank 22 this moment first, and the temperature of cold-producing medium will raise; Cold-producing medium enters the second heat absorption coil pipe 25 through the 4th high-voltage tube 24 then, and heat absorption coil pipe 25 will absorb airborne heat this moment second; Cold-producing medium enters the 3rd heat absorption coil pipe 27 through the 5th high-voltage tube 26 then, heat absorption coil pipe 27 will absorb the heat of steam this moment the 3rd, the temperature of cold-producing medium is greatly improved, meanwhile steam will be condensed into water after being absorbed heat, and condensed water will enter by condensation heat-preservation cylinder discharging tube 11 and receive water water supply tank 12 or enter cooking and heat-preservation tube inner casing 3 by cooking and heat-preservation tube filling pipe 13 and ball float water compensating valve 14.Cold-producing medium after temperature raises will be got back to the inlet tube of compressor 15 through the 6th high-voltage tube 28, and the next circulation of beginning is till boiling is qualified.For using electricity wisely, can pass through the operating frequency that frequency converter 33 is regulated compressors 15 in the later stage, thereby realize the insulation boiling.

Because cooking and heat-preservation tube, condensation heat-preservation cylinder, cooking and heat-preservation tube escape pipe 5, condensation heat-preservation cylinder air inlet pipe 6 all adopt thermal insulation layer to be incubated, speed is very slow so heat scatters and disappears, and can all absorb the entrained heat of steam, so the thermal efficiency is very high, power saving rate surpasses 80%.

Second embodiment

Fig. 2 is the second embodiment boiling schematic diagram of the utility model high-efficiency energy-saving steamer, and Fig. 3 is second embodiment cooling schematic diagram of the utility model high-efficiency energy-saving steamer; Second embodiment and first embodiment are basic identical, have just increased four-way change-over valve 34, cooled exhaust pipe 35, coolant exhaust valve 36, cooling, air discharging fan 37, water compensating valve 38; Described four-way change-over valve 34 is connected with outlet, the inlet tube of compressor 15, first high-voltage tube 16, the 6th high-voltage tube 28 of compressor 15 respectively; Described cooled exhaust pipe 35 is installed on the cooking and heat-preservation tube escape pipe 5 or is installed on the condensation heat-preservation cylinder air inlet pipe 6; Described coolant exhaust valve 36 and cooling, air discharging fan 37 are installed on the cooled exhaust pipe 35, and described water compensating valve 38 is installed on the cooking and heat-preservation tube filling pipe 13.

How does following surface analysis second embodiment cool off cooking material?

The digestion process and first embodiment are basic identical, have just increased four-way change-over valve 34 (see figure 2)s, how mainly to analyze cooling down high-temperature object (see figure 3) below.Four-way change-over valve 34 has been arranged, and steamer both can heat also and can freeze, and was equivalent to the process that heats the refrigeration in summer winter of air conditioner.

For some industry, be example with the alcoholic beverage industry, behind the material cooking of filling a wine cup for, need cool off the liquor raw material of high-temperature.At first close water compensating valve 38, and open coolant exhaust valve 36, cooking and heat-preservation tube tapping valve 30 and cooling, air discharging and fan 37, start the refrigeration key then, compressor 15 (see figure 3) of starting working, four-way change-over valve 34 will commutate, high-temperature high-pressure refrigerant will at first enter the 6th high-voltage tube 28, return compressor inlet from first high-voltage tube 16 at last.Air enters cooking and heat-preservation tube inner casing 3 through cooking and heat-preservation tube tapping valve 30, because radiator coil tube 17 no longer dispels the heat but absorbs heat at this moment, air themperature is descended, under the effect of cooling, air discharging fan 37, air after the cooling will rise, thereby realize the cooling of cooking material.

Other embodiment

The utility model is not limited to above-mentioned embodiment, above-mentioned preferred implementation only is exemplary, those skilled in the art can make the various modifications that are equal to and replacement and various combination, and obtain different embodiments according to spiritual essence of the present utility model.

Claims

1, high-efficiency energy-saving steamer, it comprises cooking and heat-preservation tube assembly, condensation heat-preservation cylinder assembly, Multisource heat pump assembly, it is characterized in that the cooking and heat-preservation tube escape pipe of described cooking and heat-preservation tube assembly links to each other with the condensation heat-preservation cylinder air inlet pipe of condensation heat-preservation cylinder assembly; The condensation heat-preservation cylinder discharging tube of described condensation heat-preservation cylinder assembly is connected with the cooking and heat-preservation tube filling pipe of cooking and heat-preservation tube assembly; The radiator coil tube of described Multisource heat pump assembly is installed in the cooking and heat-preservation tube inner casing of cooking and heat-preservation tube assembly; The 3rd heat absorption coil pipe of described Multisource heat pump assembly is installed in the condensation heat-preservation cylinder inner casing of condensation heat-preservation cylinder assembly.

2, high-efficiency energy-saving steamer according to claim 1 is characterized in that also comprising receipts water water supply tank; Described receipts water water supply tank is installed on the condensation heat-preservation cylinder discharging tube or on the cooking and heat-preservation tube filling pipe or between condensation heat-preservation cylinder discharging tube and cooking and heat-preservation tube filling pipe.

3, high-efficiency energy-saving steamer according to claim 1 is characterized in that also comprising frequency converter, cyclelog; Described cyclelog links to each other with compressor, frequency converter, liquid-level switch.

4, high-efficiency energy-saving steamer according to claim 1 is characterized in that also comprising ventilative dividing plate; Described ventilative dividing plate is installed in the cooking and heat-preservation tube.

5, high-efficiency energy-saving steamer according to claim 1 is characterized in that also comprising liquid-level switch; Described liquid-level switch is installed on the cooking and heat-preservation tube assembly.

6, high-efficiency energy-saving steamer according to claim 1 is characterized in that described cooking and heat-preservation tube assembly comprises cooking and heat-preservation tube shell, cooking and heat-preservation tube thermal insulation layer, cooking and heat-preservation tube inner casing, cooking and heat-preservation tube venthole, cooking and heat-preservation tube escape pipe, cooking and heat-preservation tube discharging tube, cooking and heat-preservation tube tapping valve, cooking and heat-preservation tube filling pipe, ball float water compensating valve; Described cooking and heat-preservation tube thermal insulation layer is installed between cooking and heat-preservation tube shell and the cooking and heat-preservation tube inner casing; Described cooking and heat-preservation tube venthole runs through cooking and heat-preservation tube shell, cooking and heat-preservation tube thermal insulation layer and cooking and heat-preservation tube inner casing; Described cooking and heat-preservation tube escape pipe links to each other with cooking and heat-preservation tube venthole; Described cooking and heat-preservation tube discharging tube passes cooking and heat-preservation tube shell, cooking and heat-preservation tube thermal insulation layer and cooking and heat-preservation tube inner casing successively; Described cooking and heat-preservation tube filling pipe passes cooking and heat-preservation tube shell, cooking and heat-preservation tube thermal insulation layer and cooking and heat-preservation tube inner casing successively, and links to each other with the ball float water compensating valve.

7, high-efficiency energy-saving steamer according to claim 1 is characterized in that described condensation heat-preservation cylinder assembly comprises condensation heat-preservation cylinder shell, condensation heat-preservation cylinder thermal insulation layer, condensation heat-preservation cylinder inner casing, condensation heat-preservation cylinder air admission hole, condensation heat-preservation cylinder air inlet pipe, condensation heat-preservation cylinder discharging tube; Described condensation heat-preservation cylinder thermal insulation layer is installed between condensation heat-preservation cylinder shell and the condensation heat-preservation cylinder inner casing; Described condensation heat-preservation cylinder air admission hole runs through condensation heat-preservation cylinder shell, condensation heat-preservation cylinder thermal insulation layer and condensation heat-preservation cylinder inner casing; Described condensation heat-preservation cylinder air inlet pipe links to each other with condensation heat-preservation cylinder air admission hole; Described condensation heat-preservation cylinder discharging tube passes condensation heat-preservation cylinder shell, condensation heat-preservation cylinder thermal insulation layer and condensation heat-preservation cylinder inner casing successively.

8, high-efficiency energy-saving steamer according to claim 1 is characterized in that described Multisource heat pump assembly comprises compressor, first high-voltage tube, radiator coil tube, second high-voltage tube, capillary-compensated valve, the 3rd high-voltage tube, the first heat absorption coil pipe, liquid reserve tank, heat exchanger fin, the 4th high-voltage tube, the second heat absorption coil pipe, the 5th high-voltage tube, the 3rd heat absorption coil pipe, the 6th high-voltage tube, anti-icing fluid; One end of described first high-voltage tube links to each other with the outlet of compressor, and the other end links to each other with radiator coil tube; Described second high-voltage tube, one end links to each other with radiator coil tube, and the other end links to each other with the capillary-compensated valve; The described first heat absorption coil pipe is installed in the liquid reserve tank, and the one end links to each other with the 3rd high-voltage tube, and the other end links to each other with the 4th high-voltage tube; The described second heat absorption coil pipe two ends link to each other with the 4th high-voltage tube, the 5th high-voltage tube respectively; The two ends of described the 3rd heat absorption coil pipe link to each other with the 5th high-voltage tube, the 6th high-voltage tube respectively; Described the 6th high-voltage tube one end links to each other with the 3rd heat absorption coil pipe, and the other end links to each other with compressor inlet tube; In the described liquid reserve tank anti-icing fluid is housed; Described heat exchanger fin is installed on the liquid reserve tank; Described radiator coil tube is installed in the cooking and heat-preservation tube inner casing.

9, high-efficiency energy-saving steamer according to claim 8 is characterized in that described Multisource heat pump assembly also comprises four-way change-over valve; Described four-way change-over valve is connected with compressor outlet pipe, compressor inlet tube, first high-voltage tube, the 6th high-voltage tube respectively.

10, high-efficiency energy-saving steamer according to claim 1 is characterized in that described steamer is a meal braizing machine, steamed wheaten foods thing machine, the food service industry precooker, steam the dish machine, the steamed meat machine, the Steamed fish machine, steam the seafood machine, the steamed sweet bun machine, steam bread producing machine, machine steams stuffed bun, the steamed dumpling handset, steam the some scheming, steam the liquor raw material machine, steam fodder machine, evaporate worker's raw material machine, steam the organic matter machine, steam the plant machine, the paper material precooker, steam the timber machine, steam the bamboo machine, steam the reed machine, steam the straw machine, steam the rattan machine, the sugaring precooker, the table-ware disinfection precooker, the sterilization precooker, the decolouring precooker, steam material distributing machine, steam clothing, steam leather machine, evaporate fine machine, the feather precooker, steam the inorganic matter machine, the industry precooker, in the agricultural precooker any one.