CN110594716A - Steam generator and steam box - Google Patents

Abstract

The invention relates to a steam generator and a steam box. The steam generator comprises a shell, a partition, a water level sensor and a heating element, wherein the partition divides a cavity of the shell into an evaporation cavity and a detection cavity, and the evaporation cavity is communicated with the detection cavity through a connecting channel at the lower part of the partition. The water level sensor is arranged in the detection cavity and can detect the water level in the detection cavity, and then the water level in the evaporation cavity is detected. The heating element only heats the evaporation cavity, and water vapor can be discharged from a steam outlet on the shell. And the water in the detection cavity is prevented from boiling and splashing on the water level sensor to influence the judgment of the water level sensor. Meanwhile, the steam outlet is communicated with the evaporation cavity, so that the quality and the efficiency of discharging the water vapor can be ensured. Meanwhile, the phenomenon that a large amount of water vapor condenses on the water level sensor when the water level sensor is cooled is avoided, the judgment of the water level sensor is influenced, the misjudgment is reduced or prevented, and the phenomenon that water is lack of water and the water is burnt in the evaporation cavity is avoided.

Description

Steam generator and steam box

Technical Field

The invention relates to the technical field of steam structures, in particular to a steam generator and a steam box.

Background

The steam generator heats water by using the heat energy of fuel or other energy sources to generate steam, and the food is cooked by using the steam. In order to secure the amount of steam, a water level sensor is generally provided for sensing the water level in the steam generator. However, since the heated water is boiled, the boiled water is easily splashed onto the water level sensor, and the water level is misjudged.

Disclosure of Invention

Accordingly, there is a need to provide a steam generator and a steam box that can avoid or reduce misjudgment of water level.

A steam generator comprising:

a housing formed with a cavity;

the separator penetrates through the cavity in the vertical direction, the separator divides the cavity into an evaporation cavity and a detection cavity, a connecting channel is formed at the lower part of the separator, the evaporation cavity is communicated with the detection cavity through the connecting channel, a steam exhaust port is formed in the shell, and the steam exhaust port is communicated with the evaporation cavity;

the water level sensor is arranged in the detection cavity; and

and the heating element is used for heating the evaporation cavity.

Above-mentioned steam generator pours water into to the cavity of casing when using, because the separator separates the cavity for evaporation chamber and detection chamber, the evaporation chamber is linked together through the interface channel of separator lower part and detection chamber, and then makes the hydroenergy in the cavity effectively pour into the evaporation chamber and detect the chamber. Because water level sensor sets up in detecting the intracavity, can detect the water level that detects the intracavity, and then realize the detection to evaporating intracavity water level. The evaporation cavity is heated by the heating element, so that water vapor is generated in the evaporation cavity and can be discharged from a steam outlet on the shell. Because the heating member only heats the water in the evaporation cavity, and then the temperature of the water in the detection cavity is lower than the temperature of the water in the evaporation cavity, the water in the detection cavity is prevented from boiling and splashing to the water level sensor, and the judgment of the water level sensor is prevented from being influenced. Meanwhile, the steam outlet is communicated with the evaporation cavity, so that the quality and the efficiency of discharging the water vapor can be effectively ensured. Simultaneously, still avoid water vapor to meet cold and condense on level sensor through level sensor in a large number, influence level sensor's judgement, further reduce or prevent that the condition of erroneous judgement from taking place, realize the accurate control of water level for the cavity can in time be mended, avoids the phenomenon that the evaporation intracavity appears the lack of water dry combustion method.

In one embodiment, the connection passage is formed by a space between a lower portion of the partition and an inner wall of the housing.

In one embodiment, the upper part of the separator is provided with a steam through hole, and the steam through hole is communicated with the evaporation cavity and the detection cavity.

In one embodiment, the steam through holes are multiple, and the multiple steam through holes are arranged at intervals on the upper part of the separator to form a mesh structure; or

The steam through hole is one.

In one embodiment, the steam outlet is arranged on the top wall of the evaporation cavity and is far away from the detection cavity.

In one embodiment, the shell is provided with a water inlet, and the water inlet is communicated with the cavity.

In one embodiment, the water inlet is arranged on the top wall of the cavity and is positioned in the middle of the top wall of the cavity.

In one embodiment, a water outlet is formed in the bottom wall of the shell and is communicated with the cavity.

In one embodiment, the heating element is arranged on the bottom wall of the evaporation cavity, and the size of the heating element is smaller than or equal to that of the bottom wall of the evaporation cavity.

A steam box, comprising:

the steam generator as described above; and

and the water vapor in the evaporation cavity can be discharged into the box body through the vapor outlet.

When the steam box is used, water is injected into the cavity of the shell, the partition separates the cavity into the evaporation cavity and the detection cavity, the evaporation cavity is communicated with the detection cavity through the connecting channel at the lower part of the partition, and therefore water in the cavity can be effectively injected into the evaporation cavity and the detection cavity. Because water level sensor sets up in detecting the intracavity, can detect the water level that detects the intracavity, and then realize the detection to evaporating intracavity water level. The evaporation cavity is heated by the heating element, so that water vapor is generated in the evaporation cavity, and the water vapor can be discharged into the box body from the steam outlet on the shell body to cook food in the box body. Because the heating member only heats the water in the evaporation cavity, and then the temperature of the water in the detection cavity is lower than the temperature of the water in the evaporation cavity, the water in the detection cavity is prevented from boiling and splashing to the water level sensor, and the judgment of the water level sensor is prevented from being influenced. Meanwhile, the steam outlet is communicated with the evaporation cavity, so that the quality and the efficiency of discharging the water vapor can be effectively ensured. Simultaneously, still avoid water vapor to meet cold and condense on level sensor through level sensor in a large number, influence level sensor's judgement, further reduce or prevent that the condition of erroneous judgement from taking place, realize the accurate control of water level for the cavity can in time be mended, avoids the phenomenon that the evaporation intracavity appears the lack of water dry combustion method.

Drawings

FIG. 1 is a front view of a steam generator in one embodiment;

fig. 2 is an enlarged view of a point a in fig. 1.

Description of reference numerals:

10. the steam generator comprises a steam generator body 100, a shell body 110, a cavity 112, an evaporation cavity 114, a detection cavity 120, a steam exhaust port 122, a steam exhaust pipe 130, a water inlet port 132, a water inlet pipe 140, a water outlet port 142, a water outlet pipe 200, a partition 210, a connecting channel 220, a steam through hole 300, a water level sensor 400 and a heating element.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein, but rather should be construed as broadly as the present invention is capable of modification in various respects, all without departing from the spirit and scope of the present invention.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not denote a single embodiment.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

Referring to fig. 1 and 2, in an embodiment of the present invention, the steam generator 10 at least can effectively reduce or avoid a misjudgment of a water level in the steam generator 10, so as to realize accurate control of the water level, so that the steam generator 10 can supplement water in time, and avoid a phenomenon that the steam generator 10 is dry-boiled due to lack of water.

The steam generator 10 includes a case 100, a partition 200, a water level sensor 300, and a heating member 400. The housing 100 is formed with a cavity 110. The partition 200 is vertically inserted into the cavity 110, and the partition 200 partitions the cavity 110 into the evaporation chamber 112 and the detection chamber 114. The lower portion of the partition 200 is formed with a connection passage 210, and the evaporation chamber 112 communicates with the detection chamber 114 through the connection passage 210. The casing 100 is provided with a steam outlet 120, and the steam outlet 120 is communicated with the evaporation cavity 112. The water level sensor 300 is disposed in the sensing chamber 114. The heating member 400 is used to heat the evaporation chamber 112.

When the steam generator 10 is used, water is injected into the cavity 110 of the housing 100, the partition 200 divides the cavity 110 into the evaporation cavity 112 and the detection cavity 114, and the evaporation cavity 112 is communicated with the detection cavity 114 through the connecting channel 210 at the lower part of the partition 200, so that the water in the cavity 110 can be effectively injected into the evaporation cavity 112 and the detection cavity 114. Since the water level sensor 300 is disposed in the detection chamber 114, the water level in the detection chamber 114 can be detected, and the water level in the evaporation chamber 112 can be detected. The evaporation chamber 112 is heated by the heating member 400, so that water vapor is generated in the evaporation chamber 112, and the water vapor can be discharged from the steam discharge port 120 of the housing 100. Because the heating element 400 only heats the water in the evaporation cavity 112, the temperature of the water in the detection cavity 114 is lower than that of the water in the evaporation cavity 112, and the water in the detection cavity 114 is prevented from being boiled and splashed onto the water level sensor 300 to influence the judgment of the water level sensor 300. Meanwhile, the steam outlet 120 is communicated with the evaporation cavity 112, so that the quality and the efficiency of water vapor discharge can be effectively ensured. Meanwhile, the phenomenon that a large amount of water vapor condenses on the water level sensor 300 when the water level sensor 300 is cooled to influence the judgment of the water level sensor 300 is avoided, the misjudgment is further reduced or prevented, the accurate water level control is realized, the cavity 110 can be supplemented with water in time, and the phenomenon that the evaporation cavity 112 is lack of water and is dried to burn is avoided.

In one embodiment, the partition 200 is a plate-shaped structure, and the partition 200 partitions the cavity 110, so as to prevent the partition 200 from occupying the cavity 110 and affecting the water storage capacity of the cavity 110. In other embodiments, the partition 200 may have other structures as long as it can separate the cavity 110 into the evaporation cavity 112 and the detection cavity 114.

In the present embodiment, the partition 200 is integrally formed in the cavity 110, which can effectively improve the stability of the partition 200 in the cavity 110. In other embodiments, the housing 100 has a mounting slot, and the spacer 200 is mounted in the mounting slot and located in the cavity 110.

In the present embodiment, the space between the lower portion of the partition 200 and the inner wall of the case 100 forms the connection passage 210. The partition 200 is prevented from interfering with the flow of water between the evaporation chamber 112 and the detection chamber 114 by creating the spacing to form the connection passage 210 so that water can efficiently flow from the evaporation chamber 112 into the detection chamber 114. Meanwhile, the formation of the connecting channel 210 at the lower part of the partition 200 by means of an opening is avoided, so that the accumulation of scale generated in the evaporation chamber 112 or the detection chamber 114 at the partition 200, which causes the blockage of the connecting channel 210, and the influence on the water level in the detection chamber 114 is avoided.

In one embodiment, the upper portion of the partition 200 is formed with a steam hole 220, and the steam hole 220 communicates the evaporation cavity 112 and the detection cavity 114. A part of the water vapor can enter the detection cavity 114 through the vapor through hole 220, so that the air pressure in the detection cavity 114 is ensured to be consistent with the air pressure in the evaporation cavity 112, and the detection accuracy of the water level sensor 300 in the detection cavity 114 is improved.

In the present embodiment, the steam passing holes 220 are plural, and the plural steam passing holes 220 are spaced apart from each other and provided at an upper portion of the partition 200 to form a mesh structure. The mesh structure formed by arranging the plurality of steam through holes 220 can effectively prevent or reduce the splashing of the boiling water in the evaporation cavity 112 and the water can pass through the steam through holes 220, so that the water boiling in the evaporation cavity 112 is prevented or splashed onto the water level sensor 300, and the misjudgment rate of the water level sensor 300 is reduced.

In other embodiments, the steam hole 220 is one, and the water vapor in the evaporation cavity 112 enters the detection cavity 114 through the steam hole 220, so as to ensure that the air pressure of the evaporation cavity 112 is consistent with that of the detection cavity 114. Alternatively, the number of the steam holes 220 may be two, three, or the like, as long as the steam can enter the detection chamber 114 from the evaporation chamber 112.

In another embodiment, the venting holes 220 may be omitted, and openings may be formed in the top or side walls of the detection chamber 114.

In one embodiment, the steam outlet 120 is disposed on the top wall of the evaporation cavity 112, so that the steam generated in the evaporation cavity 112 is directly discharged through the steam outlet 120, thereby improving the steam discharging efficiency.

Further, the exhaust port 120 is located away from the detection chamber 114. Because steam is discharged by steam vent 120, and steam vent 120 is located the position of keeping away from detecting chamber 114, can further avoid steam to enter into in a large number and detect chamber 114, and then avoid steam to condense on level sensor 300, guarantee the accuracy that level sensor 300 detected.

Of course, in other embodiments, the steam outlet 120 may be opened at other positions on the top wall of the evaporation cavity 112, as long as the steam outlet is convenient to discharge.

In this embodiment, the steam outlet 120 is provided with a steam outlet pipe 122, so as to conveniently allow the water vapor to enter a designated position or device.

In one embodiment, the housing 100 has a water inlet 130, and the water inlet 130 is connected to the cavity 110. The water inlet 130 is opened to facilitate the injection of water into the cavity 110, so that the water can be filled into the evaporation cavity 112 and the detection cavity 114. Of course, in other embodiments, the water inlet 130 may be omitted and water injected into the cavity 110 through the steam outlet 120.

Specifically, the water inlet 130 is opened on the top wall of the cavity 110 and is located at the middle of the top wall of the cavity 110. In the process of water filling, water will flow toward the circumferential direction of the water inlet 130, so as to quickly ensure that the water levels of the evaporation cavity 112 and the detection cavity 114 are consistent.

In other embodiments, the water inlet 130 may be opened at other positions of the housing 100, for example, the water inlet 130 is communicated with the detection chamber 114, so long as the water injection into the cavity 110 through the water inlet 130 can be realized.

In one embodiment, the water inlet 130 is provided with a water inlet pipe 132, and the stability of water injection can be improved through the water inlet pipe 132, so that water can be effectively injected into the cavity 110.

In one embodiment, the bottom wall of the housing 100 defines a drain opening 140, and the drain opening 140 is in communication with the cavity 110. When the steam generator 10 is not used, water is discharged through the water outlet 140, so that the phenomenon that the water in the cavity 110 is used for a long time to breed bacteria and influence the quality of water vapor is avoided.

Specifically, the drain port 140 opens on the bottom wall of the detection chamber 114. On one hand, the water outlet 140 is prevented from interfering the heating of the evaporation cavity 112 by the heating element 400, and on the other hand, the water temperature in the evaporation cavity 112 is higher, so that more scale is generated in the evaporation cavity 112, and the water outlet 140 is prevented from being blocked due to the water outlet 140 arranged in the evaporation cavity 112. Of course, in other embodiments, the drain port 140 may be opened on the bottom wall of the evaporation cavity 112, as long as the water in the cavity 110 can be effectively drained.

In one embodiment, drain port 140 is provided with a drain 142, through which drain 142 water can be conveniently drained to a designated location or sewer.

In the present embodiment, the water level sensor 300 is a water level probe. One end of the water level probe is disposed on the casing 100, and the other end thereof penetrates the detection chamber 114. The water level probe detects the water level by utilizing the difference of the electric conductivity of water and steam, and the electric conductivity of water is large and the resistance is small. When the detection point of the water level probe is submerged by water, the water level probe is in short circuit with the shell 100, the water is detected in the detection cavity 114, and the water adding is stopped; when the water level is lower than the detection point of the water level probe, the shell 100 and the water level probe are disconnected because the conductivity of the steam is small and the resistance is large, and the water is required to be supplemented when the water shortage of the steam generator 10 is detected.

In other embodiments, the water level sensor 300 may also be one of a floating ball type water level sensor, a magnetic water level sensor, an ultrasonic water level sensor, a capacitive water level sensor, etc., as long as the detection of the water level in the detection chamber 114 can be achieved.

In one embodiment, the heating member 400 is disposed on the bottom wall of the evaporation cavity 112, and the size of the heating member 400 is smaller than or equal to the size of the bottom wall of the evaporation cavity 112. Because the heating member 400 is arranged on the bottom wall of the evaporation cavity 112, and the size of the heating member 400 is smaller than or equal to the size of the bottom wall of the evaporation cavity 112, the heating member 400 effectively heats the water in the evaporation cavity 112, avoids heating the water in the detection cavity 114, and further avoids the water in the detection cavity 114 from splashing to the water level sensor 300 due to boiling.

In one embodiment, the heating element 400 is a heating tube coiled on the bottom wall of the evaporation chamber 112. In other embodiments, the heating element 400 may be a heating plate, etc., as long as the water in the evaporation cavity 112 can be heated.

The steam box in one embodiment comprises the steam generator 10 and the box body in any of the above embodiments, and the steam in the evaporation cavity 112 can be discharged into the box body through the steam outlet 120. Through the discharged water vapor, the food in the box body is effectively heated.

When the steam box is used, water enters the evaporation cavity 112 from the water inlet 130 and enters the detection cavity 114 through the connecting channel 210, and when the water level sensor 300 detects that the water level reaches a certain height, the water inlet is stopped. The heating element 400 is activated to heat the evaporation cavity 112, and the generated water vapor enters the box body from the steam outlet 120 to cook the dishes. When the water level inside the sensing chamber 114 is lower than the sensing water level, water inflow is started. After cooking, the water remained in the cavity 110 is discharged from the water outlet 140, so as to avoid affecting the next use of the steam box.

The above-mentioned embodiments only express a few embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. A steam generator, comprising:

a housing formed with a cavity;

the separator penetrates through the cavity in the vertical direction, the separator divides the cavity into an evaporation cavity and a detection cavity, a connecting channel is formed at the lower part of the separator, the evaporation cavity is communicated with the detection cavity through the connecting channel, a steam exhaust port is formed in the shell, and the steam exhaust port is communicated with the evaporation cavity;

the water level sensor is arranged in the detection cavity; and

and the heating element is used for heating the evaporation cavity.

2. The steam generator of claim 1, wherein a space between a lower portion of the partition and an inner wall of the case forms the connection passage.

3. The steam generator of claim 1, wherein the separator has a steam vent formed at an upper portion thereof, and the steam vent communicates the evaporation chamber with the detection chamber.

4. The steam generator of claim 3, wherein the steam vents are a plurality of openings spaced apart from each other at an upper portion of the partition to form a mesh structure; or

The steam through hole is one.

5. The steam generator of any of claims 1 to 4, wherein the steam outlet opens at a top wall of the evaporation chamber and is located away from the detection chamber.

6. The steam generator of any of claims 1 to 4, wherein the housing defines a water inlet, the water inlet being in communication with the cavity.

7. The steam generator of claim 6, wherein the water inlet opens at a top wall of the cavity and is located in a middle portion of the top wall of the cavity.

8. The steam generator of any of claims 1 to 4, wherein a drain opening is formed in a bottom wall of the housing, the drain opening being in communication with the cavity.

9. The steam generator of any of claims 1 to 4, wherein the heating element is disposed on the bottom wall of the evaporation chamber, the size of the heating element being less than or equal to the size of the bottom wall of the evaporation chamber.

10. A steam box, comprising:

the steam generator of any of claims 1-9; and

and the water vapor in the evaporation cavity can be discharged into the box body through the vapor outlet.