CN211066129U - Energy-saving environment-friendly efficient stockpot - Google Patents

Abstract

The utility model relates to an energy-concerving and environment-protective high-efficient slaughterhouse. The energy-saving environment-friendly efficient stockpot comprises a pot body, an outer shell frame for bearing the pot body, a circulating fire track, a fan and a fire grate, wherein the circulating fire track is of a disc-shaped single-channel pipeline structure, a fire inlet is formed in the center of the circulating fire track, an air suction port is formed in the outermost side of the circulating fire track, and the air suction port is communicated with an air suction port of the fan to form a one-way air circulation pipeline from the fire inlet to the air suction port; the central position of the circulating fire track is provided with a hollow area, the upper end of the hollow area is closed, the lower end of the hollow area is opened to form a fire inlet area, a fire outlet of the fire grate is arranged in the fire inlet area, and the fire inlet of the circulating fire track is communicated with the fire inlet area; this energy-concerving and environment-protective high-efficient slaughterhouse, design benefit, easy operation is convenient for improve the heating efficiency of slaughterhouse, the effectual thermal utilization ratio that has improved, and low in preparation cost, convenient to popularize and use.

Description

Energy-saving environment-friendly efficient stockpot

Technical Field

The utility model belongs to the technical field of the slaughterhouse heating, concretely relates to energy-concerving and environment-protective high-efficient slaughterhouse.

Background

In the manufacture of Chinese food, a lot of soup pots need to participate, especially for restaurants which pay attention to efficiency, the soup pot is often expected to have high heating efficiency, however, most of the existing soup pots are heated by coal furnaces and gas stoves, the heating efficiency is low, in recent years, many merchants directly adopt fire bars for heating, certain heating efficiency is improved, the utilization rate of heat is low, most of heat is still dissipated, and for the soup pot, the size is large, a lot of time is still needed for heating the bottom of the soup pot to boil the soup in the soup pot by using the fire bars, and troubles are brought to users of the soup pot.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an energy-concerving and environment-protective high-efficient slaughterhouse simple structure, reasonable in design in order to solve above-mentioned problem.

The utility model discloses a following technical scheme realizes above-mentioned purpose:

the utility model provides an energy-concerving and environment-protective high-efficient slaughterhouse, includes the pot body, is used for bearing the shell frame, circulation fire track, fan and the fire row of the pot body, wherein: the circulating fire track is of a disc-shaped single-pass pipeline structure, a fire inlet is formed in the center of the circulating fire track, an air suction port is formed in the outermost side of the circulating fire track, and the air suction port is communicated with an air suction port of a fan to form a one-way air circulation pipeline from the fire inlet to the air suction port; the central position of the circulating fire track is provided with a hollow area, the upper end of the hollow area is closed, the lower end of the hollow area is opened, a fire inlet area is formed, a fire outlet of the fire grate is arranged in the fire inlet area, and the fire inlet of the circulating fire track is communicated with the fire inlet area.

As the utility model discloses further optimization scheme, the interior bottom of the pot body is located to circulation fire track, the cavity region upper end that the orbital central point of circulation fire put seals, and the lower extreme passes pot body bottom surface and accesss to the external portion of pot, forms into the fire region.

As the utility model discloses further optimization scheme is equipped with the division board in orbital top of circulation fire, divide into the operating area of top and the zone of heating of below with the pot body, the surface of division board is provided with the through-hole.

As a further optimization scheme of the utility model, the inlet scoop of fan is connected with the orbital induction port of circulation fire through an induction pipe.

As a further optimization scheme of the utility model, the outer surface of the pot body and/or the circulating fire track is provided with a heat preservation layer, so that the heat quantity can be reduced and dissipated meaninglessly.

As a further optimization scheme of the utility model, the internal drain pipe that is equipped with of pot, be equipped with the water valve on the drain pipe for the discharge of the internal hot water juice of control pot.

As a further optimization scheme of the utility model, the circulating fire track is a disc-shaped structure composed of a plurality of concentric circular tubes, wherein the side surface of the innermost concentric circular tube facing the circle center forms a hollow area; the fire inlet is arranged on the side surface of the innermost concentric circular tube facing the circle center, a communication port is arranged between the adjacent concentric circular tubes, the outermost concentric circular tube is provided with an air suction port, and an air suction port of the fan is communicated with the air suction port to suck air in the circulating fire track through the air suction port; fire baffles are arranged between the communicating ports of the concentric circular pipes and the adjacent concentric circular pipes or between the communicating ports and the fire inlet/air suction ports, and the communicating ports, the fire inlet and the air suction ports of the concentric circular pipes and the adjacent concentric circular pipes are all arranged close to the fire baffles to form disc-shaped closed single-pass pipelines communicated with each other between the fire inlet and the air suction ports; the disc-shaped design can ensure that the flame has no barrier when the fan performs air draft, and the flame circulation is smoother.

The beneficial effects of the utility model reside in that: the utility model discloses a circulation fire track of setting in the hot water pot, at first circulation fire track can elongate the flame that the fire was arranged and is sent through the fan, and the flame that elongates will circulate fire track heating, realizes the hot water juice heating in the pot. The circulating fire track is arranged in the soup pot, so that the soup can be reported through the circulating fire track, and the effective utilization rate of heat can be greatly improved. Even close the fire and arrange the gas after, still can keep the pot internal to last exothermic a period, whole device design benefit, easy operation is convenient, is convenient for improve the heating efficiency of slaughterhouse, has effectively improved thermal utilization ratio, and low in preparation cost, convenient to popularize and use.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic bottom structure view of the circulating fire track of the present invention;

FIG. 3 is a schematic view of the internal structure of the circulating fire track of the present invention;

FIG. 4 is a directional diagram of the air being drawn into the track of the circulating fire track of the present invention;

FIG. 5 is a schematic view of the whole structure of the circulating fire track of the present invention disposed inside the pot body;

fig. 6 is a schematic structural diagram of the partition plate of the present invention.

In the figure: 1. a pan body; 2. circulating the fire track; 3. a fire inlet; 4. a fire entry zone; 5. an air suction port; 6. an air intake duct; 7. a fan; 8. a control panel; 9. a housing frame; 10. a heat-insulating layer; 11. a fire damper; 12. a partition plate; 13. a through hole; 14. a heating zone; 15. a hollow region; 16. a drain pipe; 17. and (4) discharging fire.

Detailed Description

The present application will now be described in further detail with reference to the drawings, it should be noted that the following detailed description is given for illustrative purposes only and is not to be construed as limiting the scope of the present application, as those skilled in the art will be able to make numerous insubstantial modifications and adaptations to the present application based on the above disclosure.

Example 1

As shown in fig. 1-4, the energy-saving environment-friendly efficient stockpot comprises a pot body 1, an outer shell frame 9 for bearing the pot body 1, a circulating fire track 2 for heating, a fan 7 and a fire grate 17, wherein the fan 7 and the fire grate are arranged on the outer shell frame 9, and the energy-saving environment-friendly efficient stockpot comprises: the circulating fire track 2 is of a disc-shaped single-pass pipeline structure, the fire inlet 3 is arranged at the center of the circulating fire track 2, the air suction port 5 is arranged on the outermost side of the circulating fire track 2, and the air suction port 5 is communicated with the air suction port of the fan 7 to form a one-way air circulation pipeline from the fire inlet 3 to the air suction port 5.

As shown in fig. 1, the circulating fire track 2 may be disposed on the outer surface of the bottom end of the pot body 1, and the circulating fire track 2 may be disposed in a circular spiral shape around the bottom of the pot body 1, as shown in fig. 2-4, the circulating fire track 2 is a disk-shaped structure composed of a plurality of concentric circular tubes, wherein the side surface of the innermost concentric circular tube facing the center of the circle forms a hollow region 15, and the outer bottom surface of the pot body 1 and the side surface of the innermost concentric circular tube facing the center of the circle form a fire inlet region 4; the fire inlet 3 is arranged on the side surface of the innermost concentric circular tube facing the circle center and communicated with the fire inlet area 4, a communication port is arranged between adjacent concentric circular tubes, the outermost concentric circular tube is provided with an air suction port 5, an air suction port of the fan 7 is communicated with the air suction port 5, and air in the circulating fire track 2 is sucked through the air suction port 5; and fire baffles 11 are arranged between the communicating ports of the concentric circular pipes and the adjacent concentric circular pipes or between the communicating ports and the fire inlet 3/air suction port 5, and the communicating ports of the concentric circular pipes and the adjacent concentric circular pipes, the fire inlet 3 and the air suction port 5 are all arranged close to the fire baffles 11 to form a disc-shaped closed single-way pipeline communicated with each other between the fire inlet 3 and the air suction port 5.

Regarding the shape of the circulating flame track 2, the spiral shape formed by concentric circular tubes is provided in the present embodiment, but the present invention is not limited thereto, and other shapes such as a square spiral shape may be provided, and in order to make the flame circulate smoothly, the turning part of the square spiral coil pipe may be set to be an arc shape, and the smooth circulation of the flame may also be ensured. The pipeline of the circulating fire track 2 adopts a metal heat conducting pipe, the circulating fire track 2 is distributed at the bottom of the pot body 1 in a disc shape, when the fan 7 sucks air through the air suction port 5 of the circulating fire track 2, flame generated at the fire inlet 3 of the fire grate 17 is sucked into the circulating fire track 2 by wind power, the flame is stretched and dispersed in the circulating fire track 2, and the heating efficiency in the pot body 1 is effectively improved.

As shown in fig. 4, the flames emitted from the fire row 17 are absorbed by the suction force of the fan 7, and the travel locus as shown by the arrow in the figure is generated. The circulating fire rail 2 is heated through the elongated flame, the circulating fire rail 2 heats the pot body 1 again, and the pot body 1 can be heated more uniformly and stably while the pot body 1 is protected due to the fact that the flame does not directly contact the pot body 1. In addition, since the flame is elongated in the circulating fire pipe, the heating area is larger, and most of the heat of the flame is locked on the circulating fire track 2, the heat utilization rate is higher.

The air suction opening of the fan 7 is communicated with the air suction opening 5 of the circulating fire track 2 through the air suction pipe 6, the air suction pipe 6 is made of stainless steel, the air suction opening 5 of the fan 7 is connected with the air suction opening 5 through the air suction pipe 6, and in actual installation, the circulating fire track 2 is in a closed state, so that a part of air can be brought in while the fan 7 adsorbs flame to assist the combustion of the flame inside the circulating fire track 2, but the air content in the track is not large, and therefore the flame cannot be discharged from the air suction opening 5. However, for the sake of safety, when the circulating fire rail 2 is installed, a centrifugal fan may be used as the fan 7, and the fan 7 is connected to the air suction port 5 through the air suction pipe 6, so that the potential safety hazard may be avoided. The power of the fan 7 can be judged according to the length of the circulating fire track 2, and the requirement of air draft can be met.

The outer surfaces of the pot body 1 and the circulating fire rail 2 are wrapped with heat insulation layers, so that the meaningless heat loss can be reduced.

In order to further improve the heat conversion efficiency and improve the heating effect of the soup in the pot body 1, as shown in fig. 5-6, the circulating fire track 2 is arranged at the inner bottom of the pot body 1, a hollow area 15 is arranged at the central position of the circulating fire track 2, the upper end of the hollow area 15 is sealed, the lower end of the hollow area 15 penetrates through the bottom surface of the pot body 1 to be led to the outside of the pot body 1, a fire inlet area 4 is formed, a fire outlet of the fire grate 17 is arranged in the fire inlet area 4, and a fire inlet 3 of the circulating fire track 2 is communicated with the fire inlet area 4. A partition plate 12 is arranged above the circulating fire track 2 and divides the pot body 1 into an upper operation area and a lower heating area 14, and a through hole 13 is arranged on the outer surface of the partition plate 12.

The pot body 1 is internally provided with a drain pipe 16, one end of the drain pipe 16 is communicated with the bottom of the pot body 1, and the other end of the drain pipe is provided with a water valve for controlling the discharge of the soup in the pot body 1.

In this embodiment, the fan 7 is a centrifugal fan of type B4-72, the driving motor is a YPT160M2-2 series variable-frequency speed-regulating three-phase asynchronous motor, and the control panel 8 of the centrifugal fan, the driving motor and the lighter switch of the fire grate 17 are all arranged at a position of the rack suitable for user operation, so as to facilitate operation.

When the gas burner is used, the fire grate 17 is communicated with external gas, flame is generated by the aid of the igniter arranged on the fire grate 17, and the flame burns in the fire inlet area 4. Start fan 7, flame is elongated in circulation fire track 2 through advancing fire door 3 entering circulation fire track 2 under the drive of fan 7, and flame is not direct contact bottom of a boiler this moment, but upwards carries out heat-conduction through the pipe wall of circulation fire track 2, and is little to the 1 injury of pot body, and the heated area is bigger more even. The user pours into the soup material of waiting to decoct in the operation district, utilizes the circulation fire track 2 heating system in the zone of heating 14 to decoct, decocts the back, discharges the soup through drain pipe 16. When circulation fire track 2 was located the pot body 1, because the existence of baffle through-hole 13, after pot body 1 was full of hot water, circulation fire track 2 was surrounded by hot water, had greatly improved the heating efficiency and the thermal utilization ratio of hot water, and is comparatively practical.

In order to verify the utility model discloses the energy utilization efficiency of slaughterhouse sets up the contrast test, utilizes the fire row 17 of equal model to heat the cold water of equal capacity and temperature, and under the same condition, 100kg water is heated to the time of boiling needs 50min under traditional slaughterhouse, adopts circulation fire track 2 to locate the invention slaughterhouse in the pot body 1 to heat only 10min, has greatly improved the heating efficiency of hot water, and, the utility model discloses the device is after closing fire row 17 gas, and circulation fire track 2 and pot body 1 can also release residual heat because the temperature itself is higher, make the difficult rapid decline of temperature in the slaughterhouse.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention.

Claims (7)

1. The energy-saving environment-friendly efficient stockpot comprises a pot body, an outer shell frame for bearing the pot body, a circulating fire track, a fan and a fire grate, and is characterized in that the circulating fire track is of a disc-shaped single-way pipeline structure, a fire inlet is formed in the center of the circulating fire track, an air suction port is formed in the outermost side of the circulating fire track, and the air suction port is communicated with an air suction port of the fan to form a one-way air circulation pipeline from the fire inlet to the air suction port; the central position of the circulating fire track is provided with a hollow area, the upper end of the hollow area is closed, the lower end of the hollow area is opened, a fire inlet area is formed, a fire outlet of the fire grate is arranged in the fire inlet area, and the fire inlet of the circulating fire track is communicated with the fire inlet area.

2. The energy-saving environment-friendly efficient stockpot according to claim 1, characterized in that: the circulating fire rail is arranged at the inner bottom of the pot body, the upper end of a hollow area at the center of the circulating fire rail is closed, and the lower end of the hollow area penetrates through the bottom surface of the pot body and leads to the outside of the pot body to form a fire inlet area.

3. The energy-saving environment-friendly efficient stockpot according to claim 1, characterized in that: a partition plate is arranged above the circulating fire track and divides the pot body into an upper operation area and a lower heating area, and through holes are formed in the outer surface of the partition plate.

4. The energy-saving environment-friendly efficient stockpot according to claim 1, characterized in that: and the air suction port of the fan is connected with the air suction port of the circulating fire track through an air suction pipe.

5. The energy-saving environment-friendly efficient stockpot according to claim 1, characterized in that: and the outer surface of the pot body and/or the circulating fire track is/are provided with a heat insulation layer.

6. The energy-saving environment-friendly efficient stockpot according to claim 1, characterized in that: the pot body is internally provided with a drain pipe, and the drain pipe is provided with a water valve.

7. The energy-saving environment-friendly efficient stockpot according to claim 1, characterized in that: the circulating fire track is of a disc-shaped structure consisting of a plurality of concentric circular tubes, wherein the side surface of the innermost concentric circular tube facing the center of the circle forms a hollow area; the fire inlet is arranged on the side surface of the innermost concentric circular tube facing the circle center, a communication port is arranged between the adjacent concentric circular tubes, the outermost concentric circular tube is provided with an air suction port, and an air suction port of the fan is communicated with the air suction port to suck air in the circulating fire track through the air suction port; fire baffles are arranged between the communicating ports of the concentric circular pipes and the adjacent concentric circular pipes or between the communicating ports and the fire inlet/air suction ports, and the communicating ports, the fire inlet and the air suction ports of the concentric circular pipes and the adjacent concentric circular pipes are all arranged close to the fire baffles to form disc-shaped closed single-pass pipelines communicated with each other between the fire inlet and the air suction ports.

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