CN115500687A - Quick steam pot - Google Patents

Abstract

The invention discloses a rapid steam pot. The disclosed fast steam pot comprises a pot lower body and a pot upper body; the upper part of the pot forms a steam heating cavity; a steam forming cavity and a water storage cavity are formed on the lower body of the cooker; the bottom of the steam forming cavity is a heated plate; an opening at the upper part of the steam forming cavity forms a steam outlet communicated with the lower part of the steam heating cavity; a water replenishing port is arranged between the water storage cavity and the steam forming cavity; when the amount of water in the steam forming chamber is reduced, the water in the water storage chamber is automatically replenished into the steam forming chamber under the action of gravity, and the steam forming chamber can be kept boiling due to the fact that the water replenishing is continuous and the amount of the water replenishing is relatively small, and then the steam is continuously formed and output. By utilizing the rapid steam cooker provided by the patent, as only water in the steam forming cavity needs to be heated, the water in the steam forming cavity can be rapidly boiled, and steam is rapidly formed and output; meanwhile, the water storage cavity can continuously supplement the amount of water converted into steam to the steam forming cavity, the steam forming cavity is kept boiling, and steam can be continuously generated.

Description

Quick steam pot

Technical Field

The invention relates to a cooking utensil, in particular to a quick steam pot.

Background

Among various cooking methods, steaming is one of the commonly used methods. Steaming is a method of processing raw materials by using water vapor as a heat transfer medium. The food cooked (i.e. steamed) by the steaming method can ensure uniform heating, reduce or avoid excessive damage to food components and maintain the nutrition of the food; the steamed food is also healthier compared to fried food.

The currently common steaming cooking device is a steamer, and water at the bottom of the steamer is heated to boiling by a heat source to form steam; the formed steam reaches a steam heating cavity which is arranged at the upper part and used for placing food raw materials, and the food raw materials are heated and steamed in the steam heating cavity to form a preset food finished product or semi-finished product. In order to improve the steaming efficiency, in the related art, a steamer is generally manufactured using a material having a better thermal conductivity, or a steamer is generally manufactured by heating water to boil as quickly as possible to form steam and steaming a food material with the steam. Of course, if the amount of water in the steamer is small, the water can be heated to boiling more quickly, but the steaming time cannot be kept long.

How to obtain the steam needed for steaming more quickly and keep steaming time longer becomes the direction of effort of the technicians in this field.

Disclosure of Invention

The invention aims to provide a quick steam cooker, which can obtain steam required by steaming more quickly, can continuously generate steam and can keep a longer steaming time.

The invention provides a rapid steam cooker which comprises a cooker lower body and a cooker upper body; the upper body of the pot forms a steam heating cavity for placing or containing food raw materials to be steamed; the pot lower body forms a steam forming cavity for generating steam and a water storage cavity for storing standby water; the bottom of the steam forming cavity is a heated plate to heat water in the steam forming cavity and form steam after boiling; an opening at the upper part of the steam forming cavity forms a steam output port communicated with the lower part of the steam heating cavity, so that the formed steam can be conveyed into the steam heating cavity to heat and steam food raw materials; a water replenishing port is arranged between the water storage cavity and the steam forming cavity, and the water replenishing port is lower than the preset water level of the steam forming cavity and lower than the preset water storage level of the water storage cavity; when the water amount in the steam forming cavity is reduced, the water in the water storage cavity can be automatically supplemented into the steam forming cavity under the action of gravity, and the steam forming cavity can be kept boiling due to continuous and small water supplement, so that steam is continuously formed and output. By utilizing the rapid steam cooker provided by the patent, as only water in the steam forming cavity needs to be heated, the water in the steam forming cavity can be rapidly boiled, and steam is rapidly formed and output; meanwhile, the water storage cavity can continuously supplement the amount of water converted into steam to the steam forming cavity, the steam forming cavity is kept boiling, and steam can be continuously generated.

In a further technical scheme, the quick steam cooker comprises a plurality of water storage cavities, and the plurality of water storage cavities are located on the periphery of the steam forming cavity.

In a further technical scheme, the water storage cavity and the steam forming cavity are separated by an annular separating ring, and the water storage cavity is of an annular structure surrounding the periphery of the steam forming cavity. Therefore, the water storage cavity can absorb the radiant heat of the steam forming cavity, so that on one hand, the function of preheating the water or supplemented water in the water storage cavity is achieved, and the continuous boiling of the steam forming cavity is further ensured; on the other hand, the heat waste can be reduced, and the energy-saving effect is improved.

In a further optional technical scheme, at least a part of the transverse sectional area of the steam forming cavity is gradually reduced from bottom to top; thus being beneficial to improving the rising speed of the steam and improving the steaming efficiency of the steam.

In a further technical scheme, the water replenishing port is provided with a one-way valve plate communicated from the water storage cavity to the steam forming cavity. This ensures smooth replenishment of water and reduces outward flow of the vapor forming chamber.

In a further technical scheme, the rapid steam cooker further comprises a steam transition cavity, and the steam outlet is communicated into the steam heating cavity through the steam transition cavity. Therefore, the steam control can be convenient, and different steaming requirements can be met.

In a further technical scheme, the steam heating cavity and the water storage cavity are both provided with air pressure balance holes. Therefore, the steam heating cavity and the water storage cavity can be ensured to have proper pressure, the pressure balance is kept, the water in the water storage cavity is ensured to be smoothly and automatically supplemented into the steam heating cavity, and power mechanisms such as a water pump and the like are not required to be arranged.

In a further technical scheme, the rapid steam cooker further comprises a heating assembly corresponding to the heated plate. The use of the rapid steam cooker can be facilitated by the aid of the heating assembly. Of course, the water of the steam forming chamber may also be heated using external heating means.

In a further technical scheme, the heating assembly comprises a heating fixing ring, and the heating fixing ring surrounds the periphery of the heated plate. Therefore, the heating device can be ensured to only heat the steam forming cavity, the heating efficiency is improved, the efficiency of producing steam in the steam forming cavity is accelerated, and the steam supply continuity is ensured.

In a further technical scheme, the outer wall of the water storage cavity is a transparent outer wall, or is provided with a transparent observation window, or is provided with a water quantity detection mechanism, so that the water quantity in the water storage cavity can be determined; the water storage cavity is provided with a water filling port so as to fill water into the water storage cavity in time.

Drawings

Fig. 1 is a sectional view of the rapid steamer provided by the embodiment of the invention, and simultaneously illustrates the working principle of the rapid steamer.

Fig. 2 is an exploded view of the rapid steamer, illustrating the components of the rapid steamer.

Detailed Description

The embodiments provided by the invention are described below with reference to the accompanying drawings. In this document, the use of the terms "upper" and "lower" are defined with reference to the use status of the rapid steamer.

Referring to fig. 1 and 2, fig. 1 is a sectional view of a rapid steamer according to an embodiment of the present invention, and illustrates the operation principle of the rapid steamer. Fig. 2 is an exploded view of the rapid steamer provided in the example, illustrating the components of the rapid steamer. The rapid steamer provided by the embodiment of the invention comprises a lower body 100 and an upper body 200.

The pot upper body 200 includes an upper case 201, a cover 202, and a steam rack 203. The lid 202 cooperates with the upper opening of the upper housing 201 to define a steam heating chamber 210 therein for receiving or containing the food ingredients to be steamed. The lower floor of the upper case 201 is closed at its periphery, and a middle portion thereof is formed with a through part corresponding to a steam outlet 112 of the steam forming chamber 110, which will be described later, to allow steam to enter the steam heating chamber 210. For steaming, in this embodiment, the inner wall of the upper case 201 also forms a support step. The pot upper body 200 further includes a steaming rack 203 engaged with the supporting step to place the food materials to be steamed.

In this embodiment, the lower body 100 includes a lower casing 101 and a separation ring 102. The lower case 101 includes an annular plate in the middle of which the partition ring 102 is located, and the annular plate and the lower end of the partition ring 102 are closed by an annular bottom plate, and the upper portion of the annular bottom plate forms a water storage chamber 120 for storing the standby water. The upper opening of the water storage chamber 120 is opposite to the peripheral closed portion of the bottom plate of the upper case 201, and covers the upper opening of the water storage chamber 120. The lower portion of the separating ring 102 is closed by a heated plate 111, and the upper portion of the heated plate 111 forms a vapor forming chamber 110 that generates vapor. The steam forming chamber 110 is opened at an upper portion thereof to be opposite to a through portion of a middle part of a bottom plate of the upper case 201 to output the generated steam.

In this embodiment, the bottom surface of the water storage chamber 120 is substantially equal in height to the bottom surface of the steam forming chamber 110. A water replenishing port 121 communicated with the inside and the outside is also arranged near the bottom edge part of the separating ring 102. The water replenishment port 121 is located between and communicates the water storage chamber 120 and the steam forming chamber 110.

In use, a proper amount of water is added to the water storage cavity 120 and the steam forming cavity 110, and the water level of the water storage cavity 120 and the water level of the steam forming cavity 110 are maintained to be equal due to the communication function of the water replenishing port 121. The water replenishing port 121 is close to the bottom, is lower than the steam outlet 112, is lower than the preset water storage level of the water storage cavity 120, and has a height difference of H. The water level of the water storage chamber 120 and the water level of the steam forming chamber 110 can maintain a water-tight seal of the water replenishing port 121.

The heated plate 111 at the lower portion of the vapor forming chamber 110 may then be heated by a heat source or heating device (e.g., an external liquefied gas cooker) to boil water in the vapor forming chamber 110 to form vapor. The formed steam reaches the steam via the steam outlet 112 of the steam forming chamber 110. However, in case of abnormal pressure (such as opening or closing the cover 202 in the middle), in order to prevent the water in the steam forming chamber 110 from flowing backward and to ensure the temperature of the steam forming chamber 110, and further to keep the water in the steam forming chamber 110 boiling, the water replenishing opening 121 may be provided with a check valve plate communicated from the water storage chamber 120 to the steam forming chamber 110, so as to ensure smooth replenishment of the water and to reduce outward flow of the steam forming chamber 110.

In the illustrated embodiment, the water storage chamber 120 and the steam forming chamber 110 are separated by an annular divider ring 102, and the water storage chamber 120 is in an annular configuration around the periphery of the steam forming chamber 110. Thus, the water storage cavity 120 can absorb the radiant heat of the steam forming cavity 110, thereby playing a role of preheating the water or supplemented water in the water storage cavity 120 on one hand, and further being beneficial to ensuring the continuous boiling of the steam forming cavity 110; on the other hand, the heat waste can be reduced, and the energy-saving effect is improved.

In another embodiment, to better "separate" the water storage chamber 120 from the steam forming chamber 110, avoid the steam forming chamber 110 from transferring excessive heat to the water storage chamber 120, ensure the temperature of the steam forming chamber 110, and maintain the steam forming chamber 110 continuously boiling, the separating ring 102 may be configured in a double-layer vacuum structure, i.e., the separating ring 102 includes an inner layer and an outer layer, and the inner layer and the outer layer are vacuumed, thereby reducing the heat transfer from the steam forming chamber 110 to the water storage chamber 120 through "conduction". Further, to reduce the heat transfer to the water storage cavity 120 by "radiation", the inner surface of the outer layer of the spacer ring 102 may be configured as a reflective surface, and the outer surface of the inner layer may be configured as a rough or black surface to absorb the reflected radiation heat.

Of course, in the case where the partition ring 102 has a double-layer vacuum structure, the water replenishment port 121 may be formed by a pipe passing through the double-layer vacuum structure. In order to preheat the water introduced into the steam forming chamber 110 through the water replenishment port 121, a preheating passage extending a predetermined distance in a circumferential direction may be provided in an inner layer of the partition ring 102, so that the replenished water passes through the preheating passage and then enters the steam forming chamber 110, thereby increasing the temperature of the water in the replenished steam forming chamber 110 and ensuring continuous boiling of the steam forming chamber 110.

It is understood that one fast steamer may include a plurality of water storage chambers 120 with the plurality of water storage chambers 120 located at the periphery of the steam forming chamber 110.

As shown in fig. 1 and 2, at least a portion of the transverse cross-sectional area of the steam forming chamber 110 delivers the formed steam from the lower heating chamber 210 to the steam heating chamber 210 to heat and steam the food ingredients. Since only the water of the steam forming chamber 110 needs to be heated, the water in the steam forming chamber 110 can be boiled quickly, and steam is formed and output quickly.

Due to the communication function of the water replenishing port 121, when the amount of water in the steam forming chamber 110 is reduced due to the formation of steam by evaporation, the water in the water storage chamber 120 is automatically replenished into the steam forming chamber 110 under the action of gravity, so that the water level of the water storage chamber 120 and the water level height of the steam forming chamber 110 are kept to be substantially equal. Since the replenishment of water is continuous and relatively small in amount, the water of the steam forming chamber 110 can be kept boiling, thereby maintaining the steam output. Since the water storage chamber 120 can continuously replenish the steam forming chamber 110 with the amount of water converted into steam and keep the steam forming chamber 110 boiling, steam can be continuously generated.

In this embodiment, the water storage chamber 120 is connected to the external atmosphere. It can be understood that if the steam heating chamber 210 and the steam forming chamber 110 have good sealing performance and the internal air pressure is higher than the air pressure of the water storage chamber 120, the water level of the steam forming chamber 110 can be lower than the water level of the water storage chamber 120, but the water replenishing port 121 is lower than the predetermined water level of the water storage chamber 120, and at the same time, the liquid water can keep the water-tight sealing of the water replenishing port 121 below the predetermined water level of the steam forming chamber 110, so as to achieve the purpose of the present invention.

From the foregoing, it will be appreciated that the steam formation chamber 110, the water storage chamber 120, and the steam heating chamber 210 are not limited to being implemented by the above-described structure, and may be implemented by other specific structures, such as a sealing plate that is connected to the top edge of the spacer ring 102 and the top edge of the lower housing 101 may be provided at the upper opening of the water storage chamber 120; the lower opening of the steam heating cavity 210 can be matched with the part of the cooker lower body 100 to keep the proper sealing degree of the lower part; the upper end of the steam forming chamber 110 may extend into the steam heating chamber 210 and form a suitable steam outlet 112 on the periphery, and so on.

In addition, the specific structure of the water replenishing port 121 can also be set according to actual needs, such as setting a curve or a venturi shape.

It should be noted that, during the use process, the water in the steam forming chamber 110 is continuously boiling, part of the water is continuously converted into steam, and the water in the steam forming chamber 110 is continuously reduced, so that the water in the water storage chamber 120 is continuously replenished to the steam forming chamber 110 through the water replenishing port 121, therefore, the water flowing from the water storage chamber 120 to the steam forming chamber 110 through the water replenishing port 121 is gradually reduced upwards in the normal state; therefore, the steam rising speed is improved, and the steam steaming efficiency is improved. It will be appreciated that in order to facilitate steam control to suit different steaming requirements, the rapid steamer may further comprise a steam transition chamber through which the steam outlet 112 leads into the steam heating chamber, and through which a steam flow is directed to bring the steam to a predetermined position.

The steam heating cavity 210 and the water storage cavity 120 may be both provided with air pressure balancing holes, for example, air holes may be provided on the lid 202 as air pressure balancing holes to exhaust steam, so that the steam heating cavity 210 maintains a proper pressure; the water storage chamber 120 may be kept in communication with the atmosphere through an air pressure balancing hole. Therefore, the proper pressure in the steam heating cavity 210 and the water storage cavity 120 can be ensured, the pressure balance is kept, and the water in the water storage cavity 120 is ensured to be smoothly and automatically supplemented into the steam heating cavity 210 without arranging a power mechanism such as a water pump and the like.

It is understood that the air pressure balance can also be achieved through the fit clearance, for example, the air pressure balance of the steam heating chamber 210 can be achieved through the fit clearance between the upper casing 201 and the cover 202, and the air pressure balance of the water storage chamber 120 can be achieved through the fit clearance between the upper end of the lower casing 101 and the bottom plate of the upper casing 201.

In the embodiment shown in fig. 1 and 2, the rapid steamer further comprises a heating assembly 300 corresponding to the heated plate 111. The heating assembly 300 may be fixed to the bottom of the pot lower body 100. In this embodiment, the heating assembly 300 may be an electric heating assembly, and may include a heating fixing ring 310, a heating plate 320, and a silicone ring 330. The heating fixing ring 310 fixes the heating plate 320 and the silicone ring 330 at the bottom of the pot lower body 100, and makes the heating plate 320 opposite to the heated plate 111. The heating fixing ring 310 in this embodiment is disposed around the periphery of the heated plate 111. This ensures that the heating device heats only the vapor forming chamber 110, improves the heating efficiency, improves the efficiency of the vapor forming chamber 110 in producing vapor, and ensures the continuity of the vapor supply. The self-contained heating assembly 300 can facilitate the use of the rapid steamer.

In order to protect the heating plate 320 and the silicone ring 330 from burning accidents, the heating assembly 300 further includes a bottom cover 340 located at the outside. Since the bottom cover 340 is fixed under the pot lower body 100, the bottom cover 340 also functions as a support.

Of course, it is understood that the heating assembly 300 is not limited to an electrical heating assembly, but may be a liquefied gas, carbide, or other heating assembly. Of course, external heating means may also be used to heat the water of the steam forming chamber 110.

Of course, the heating assembly 300 may further include a dry-heating preventing device for controlling the heating assembly 300 to stop heating according to the detected temperature or other parameters when the heating assembly 300 is dry-heated without water in the steam forming chamber 110.

In a further embodiment, the outer wall of the water storage cavity 120 is a transparent outer wall, or is provided with a transparent observation window, and the water storage cavity 120 is provided with a water injection port. Therefore, the water amount in the water storage cavity 120 can be determined through the transparent outer wall or the transparent observation window, and water is added to the water storage cavity 120 through the water filling port in time, so that the working continuity of the rapid steam cooker is kept. Of course, the water level detection means may detect the water level in the water storage chamber 120, and the water level in the water storage chamber 120 may be determined by the water level detection means.

The embodiments provided by the present invention have been described in detail above. The principles and embodiments of the present invention have been described herein using specific examples, which are presented only to assist in understanding the core concepts of the present invention. It should be noted that, for those skilled in the art, it is possible to make various improvements and modifications to the present invention without departing from the principle of the present invention, and those improvements and modifications also fall within the scope of the claims of the present invention.

Claims (10)

1. A rapid steam pot comprising a pot lower body (100) and a pot upper body (200), the pot upper body (200) forming a steam heating chamber (210), characterized in that the pot lower body (100) forms a steam forming chamber (110) for generating steam and a water storage chamber (120) for storing standby water; the bottom of the steam forming cavity (110) is a heated plate (111); the upper part of the steam forming cavity (110) is opened to form a steam outlet (112) communicated with the lower part of the steam heating cavity (210); a water replenishing port (121) is arranged between the water storage cavity (120) and the steam forming cavity (110), and the water replenishing port (121) is lower than the preset water level of the steam forming cavity (110) and lower than the preset water storage level of the water storage cavity (120).

2. The fast steam cooker according to claim 1, comprising a plurality of said water storage cavities (120), a plurality of said water storage cavities (120) being located at the periphery of said steam forming cavity (110).

3. The rapid steamer according to claim 1, characterized in that the water storage chamber (120) and the steam forming chamber (110) are separated by an annular separating ring (102), and the water storage chamber (120) is in an annular configuration around the periphery of the steam forming chamber (110).

4. The rapid steamer according to claim 1, characterized in that at least a part of the transverse cross-sectional area of the steam forming chamber (110) decreases from bottom to top.

5. The fast steam kettle according to claim 1, characterized in that the water replenishing opening (121) is provided with a one-way valve plate which is communicated from the water storage cavity (120) to the steam forming cavity (110).

6. The rapid steamer according to any one of claims 1 to 5, further comprising a steam transition chamber through which the steam outlet (112) opens into the steam heating chamber (210).

7. The rapid steamer according to any one of claims 1 to 5, wherein the steam heating chamber (210) and the water storage chamber (120) are provided with air pressure balancing holes.

8. The fast steam cooker according to any of the claims 1 to 5, further comprising a heating assembly (300) corresponding to the heated plate (111).

9. The rapid steamer according to claim 8, wherein the heating assembly (300) comprises a heating collar (310), the heating collar (310) being arranged around the periphery of the heated plate (111).

10. The rapid steam cooker according to any one of claims 1 to 5, characterized in that the outer wall of the water storage cavity (120) is a transparent outer wall, or is provided with a transparent observation window, or is provided with a water amount detection mechanism; the water storage cavity (120) is provided with a water injection port.

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