KR101971565B1 - Steam valve, lid and liquid heating container - Google Patents

Abstract

The present invention relates to a steam valve, a lid and a liquid heating container, wherein the steam valve includes an exhaust pipe, an intake pipe and a weight member, the exhaust pipe having one end opened and the other end sealed, There is a free-rotating portion for allowing the exhaust pipe to rotate in its axial direction. The intake pipe is connected to the exhaust pipe and extends along the lateral direction of the exhaust pipe. A weight member connects the exhaust pipe and extends along the lateral direction of the exhaust pipe. Wherein the weight member and the intake pipe have a narrow angle alpha greater than 90 DEG and less than or equal to 180 DEG in the circumferential direction of the exhaust pipe and a gravity moment of rotation of the weight member about the free- Is larger than the rotating gravity moment. The technical solution of the present invention reduces the probability of water in the liquid heating vessel entering the exhaust pipe and improves the overflow prevention effect of the liquid heating vessel.

Description

Steam valve, lid and liquid heating container

FIELD OF THE INVENTION [0002] The present invention relates to the field of liquid heating vessels and more particularly to a type of steam valve, lid and liquid heating vessel.

Liquid heating vessels include a lid and a port body, and an enclosed assembly method, usually used between the lid and the port body, prevents the risk of burns resulting from the hot water flowing out of the port after the liquid heating vessel has been accidentally tilted. In addition, the steam valve in the lid drains water vapor from the liquid heating vessel when the water boils.

However, all of the conventional steam valves block the vent hole by the sealing mechanism. That is, when a sealing weight is additionally installed in the exhaust pipe of the steam valve, when the liquid heating container is tilted, it moves to the sealing additional exhaust port to block the exhaust port, thereby preventing overflow of the water in the port body. However, the sealing weights are often not reliably blocked, or they are not immediately blocked and often leak out of the lid.

The main object of the present invention is to provide a kind of steam valve which improves the overflow prevention effect of the liquid heating vessel.

In order to achieve the above object, a kind of steam valve provided by the present invention includes the following. The exhaust pipe is in the shape of one end opened and the other end sealed, and the exhaust pipe has a free rotation portion for allowing the exhaust pipe to rotate in its axial direction. The intake pipe is connected to the exhaust pipe, and extends along the lateral direction of the exhaust pipe. A weight member connects the exhaust pipe, and extends along the lateral direction of the exhaust pipe. Wherein the weight member and the intake pipe have a narrow angle alpha greater than 90 DEG and less than or equal to 180 DEG in the circumferential direction of the exhaust pipe and a gravity moment at which the weight member rotates around the free- Is larger than the rotating gravity moment.

As an optimization, the intake pipe is installed in a flat shape, and the length of the intake pipe is between 3 cm and 5 cm.

As the optimization, the intake pipe and the exhaust pipe are integrated, and the intake pipe extends out along the radial direction of the exhaust pipe, and is on the same rotation plane as the weight member.

As a result of optimization, the weight member and the intake pipe have a circumferential directional angle a of greater than or equal to 170 degrees and less than or equal to 180 degrees.

As optimization, there is a projection on the side wall of the exhaust pipe, and the weight member is detachably installed on the projection.

Optimally, the exhaust pipe is a plastic member, the weight member is a metal member, and the weight member is fixed on the exhaust pipe through a secondary injection.

As an optimization, the weight member is fan-shaped and its centrifugal end is connected to the exhaust pipe.

As the optimization, the outer surface of the exhaust pipe has a watertight structure, and the watertight structure includes at least a first blocking ring provided on the outer wall of the exhaust pipe and / or a second blocking ring provided on the end face of the exhaust pipe opening end, The plurality of one blocking rings are arranged in order along the axial direction of the exhaust pipe, and the plurality of second blocking rings are distributed along the radial direction of the exhaust pipe.

As the optimization, the cross sectional area of the intake pipe is S? [20 mm ² , 120 mm ² ], the length of the intake pipe is L _0? [20 mm, 60 mm], the intake pipe is provided in a flat shape, Are installed in an elliptical shape.

As an optimization, there is an abrasion resistant layer at the opening end of the exhaust pipe and / or the free rotation part.

Another type of lid provided by the present invention includes a cap body, an upper cover plate and a lower cover plate at upper and lower ends of the cap body, and a steam valve. The cap body includes a steam passage having one end connected to the exhaust pipe opening end and the other end connected to the outside, and the lid includes a rotation installing portion for installing the free rotation portion.

As the optimization, there is a receiving groove for receiving the steam valve on the cap body, and the receiving groove is in the form of a cylinder having one end closed and the other end opened, and the opening end face of the exhaust pipe is formed into a closed end face And an exhaust hole for connecting the exhaust pipe and the steam passage is formed in a closed end surface of the receiving groove.

As an optimization. There is at least one blocking groove in the end face of the closed end of the receiving groove and a first blocking ring inserted into the at least one blocking groove in the end face of the exhaust pipe opening end.

As an optimization, there is a second blocking ring on the side of the exhaust pipe that extends toward at least one of the receiving groove inner walls.

And the sealing weight is moved toward the open end of the exhaust pipe from the closed end of the exhaust pipe to seal the exhaust hole of the receiving groove closed end when the inclination angle of the exhaust pipe is greater than 90 degrees, Wherein an air guide mechanism is provided on an inner wall of the exhaust pipe, and the air guide mechanism forms an air guide passage between the sealing weight and the inner wall of the exhaust pipe, the air guide mechanism extending along the exhaust pipe axial direction, And the air guide passage is formed between the ribs adjacent to each other, and the sealing weight is provided in a columnar shape or a ball shape.

Wherein the free rotation portion is a rotation shaft provided on a cross section of the exhaust pipe closed end, the rotation installation portion is a shaft hole provided in the lower cover plate, the rotation shaft is inserted into the shaft hole, Wherein the elastic member is installed so as to surround the rotating shaft, and the exhaust pipe has a sleeve extending from the closed end face thereof, The sleeve is installed to surround the elastic member.

As an optimization, the cap body also has an outlet valve, a second receiving groove for receiving the outlet valve, and an outlet passage connecting the outlet valve and the outside, the steam passage being connected to the outlet passage.

As the optimization, the free rotation portion is a shaft hole provided in the exhaust pipe closed end, and the rotation installing portion is a rotation shaft installed in the lower cover plate and inserted into the shaft hole. Or the free rotation portion is a bearing installed at the exhaust pipe opening end, and the rotation installing portion is a bearing hole for installing the bearing on the cap body.

As an optimization, the sum of the closed space the volume formed between the watertight mechanism and the receiving groove wall is V _0, the total volume between the exhaust pipe and the receiving groove wall is _{V 1, V 0 / V 1} ∈ [0.5, 0.95].

Optimally, there is at least one blocking groove in the cross section of the receiving groove sealing end, and the second blocking ring is inserted in the blocking groove.

Optimally, the length of the intake tract is L ₀ , the radius of the lower cover plate is R, L _{0 /} R ∈ [0.6, 0.9], and the rotary mounting portion has an abrasion resistant layer.

As a result of the optimization, the gravity moment at which the weight member rotates around the free rotation portion is larger than the sum of the gravity moment at which the intake tube rotates around the free rotation portion and the frictional force moment between the cap body at the time the exhaust tube rotates.

Optimally, the weight m ₁ of the weight member is greater than or equal to 10 g and less than or equal to 50 g, and the mass m ₂ of the intake tract is greater than or equal to 5 g and less than or equal to 20 g.

Optimally, the weight of the weight member is G ₁ , the weight of the intake tract is G ₂ , and G ₁ / G ₂ ∈ [0.5, 12] or [1, 10].

The distance between the center of the weight member and the axis of the exhaust pipe is L ₁ , the distance between the center of the intake pipe and the axis of the exhaust pipe is L ₂ , L ₁ / L ₂ ∈ [2,20] Or [4,15].

As an optimization, the cap body includes an upper cover plate, a lower cover plate and a bracket, the bracket being between the upper cover plate and the lower cover plate and having a receiving groove for receiving the steam valve, And an exhaust hole for connecting the exhaust pipe and the steam passage is formed in a closed end face of the receiving groove, and an exhaust hole for connecting the exhaust pipe and the steam passage is formed in a closed end face of the receiving groove, Wherein the elastic member is a spring and the inner diameter of the spring is D? [10 mm, 20 mm], the total number of revolutions n? [4, 12], A stiffness coefficient k? [10 g / mm, 40 g / mm] and a mass m3? [0.3 g, 1.5 g], and the exhaust pipe has a slit And that the sleeve is provided around the elastic member.

As an optimization, the bracket also has an outlet valve, a second receiving groove for receiving the outlet valve, and an outlet passage connecting the outlet valve and the outside, wherein the steam passage is connected to the outlet passage.

The liquid heating vessel of the present invention also includes a port body and a lid as described in claim 18, wherein the lid seals the port body and is hermetically connected to the inner wall of the port body.

Optimally, there is a sealing ring between the lower cover plate and the cap body, and the lid is hermetically connected to the inner wall of the port body through the sealing ring.

Optimally, the lid and the port body are connected through a snap structure, which includes a flexible latch mounted on the lid and a slot provided in the lid interior of the port body.

According to the technical solution of the present invention, the steam valve is freely rotated under the driving action of the weight member through the weight member and the free rotation portion provided in the exhaust pipe, so that when the overflow preventing liquid heating container is inclined, As the engine is moved upward, the position of the intake tube is raised, the probability of water in the liquid heating vessel entering the exhaust hole is reduced, and the overflow preventing effect of the liquid heating vessel is improved.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiments of the invention and, It is to be understood that other drawings may be obtained based on the structure shown in the drawings without the creative efforts of the general practitioners of the present invention.
Brief Description of the Drawings Fig. 1 is a structural wiring diagram of an embodiment of an overflow preventing kettle of the present invention,
Figure 2 is a cross-sectional view of the lid of Figure 1,
FIG. 3 is a connection diagram of the inner structure of the lid shown in FIG. 1, wherein the lower cover plate of the lid is removed,
Fig. 4A is a structural connection diagram of an embodiment of the present invention steam valve in Fig. 3,
Fig. 4B is a structural connection diagram of another embodiment of the steam valve of the present invention shown in Fig. 3,
Fig. 5A is a structural schematic view of another view of Fig. 4A,
Fig. 5B is a schematic view showing another structure of Fig. 4B,
FIG. 6A is a cross-sectional view of the steam valve in FIG. 4A,
FIG. 6B is a sectional view of the steam valve in FIG. 4B,
FIG. 7 is a sectional view of another embodiment of the steam valve of the present invention mounted on a lid,
FIG. 8A is a cross-sectional view of the positional structure of the water and the lid after the lid is inclined at 180 DEG in FIG. 1, wherein the used steam valve is the steam valve in FIG.
FIG. 8B is a cross-sectional view of the positional structure of the water and the lid after the lid is inclined by 180 DEG in FIG. 1, wherein the steam valve used in FIG. 4B is the steam valve in FIG.

BRIEF DESCRIPTION OF THE DRAWINGS Embodiments of the present invention will now be described, by way of example only, with reference to the accompanying drawings, in which:

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention. Based on the embodiments of the present invention, all other embodiments obtained by the general artisans of this field on the assumption that there is no creative effort are all within the scope of the present invention.

Incidentally, if a directional instruction (e.g., up, down, left, right, front, back ...) is associated with an embodiment of the present invention, It is used only as a positional relationship description, and if its specific appearance changes, its directional orientation also changes accordingly.

In addition, if the description of "first", "second", etc. is related to the embodiment of the present invention, the explanation of "first", "second", etc. is used for the purpose of explanation only, I can not understand it in quantities that specify, implicitly, or implicitly, or implicitly the technical features that I have directed. Thus, if " first " is defined, then the " second " feature may include at least one of the features explicitly or implicitly. In addition, although the technical solutions between the embodiments can be combined with each other, they are necessarily based on what can be implemented by the general technicians of this field, and when there is a contradiction in the combination of technical solutions or can not be realized, It should be understood that the combination does not exist and does not exist within the claimed scope of the invention.

The present invention provides a kind of steam valve, a lid for installing the steam valve, and a liquid heating container having the lid.

1 to 3, the liquid heating vessel 10 includes a lid 10a, a port body 10b and a power supply unit 10c, of which the lid 10a is connected to the cap body 10 ' And an upper cover plate 11 installed at an upper end of the cap body 10 'and a lower cover plate 12 installed at a lower end of the cap body 10'. For convenience of explanation, the liquid heating container of the following contents will be described by taking a kettle as an example.

The cab body 10 'has a bracket 13 and a bracket 13 is provided with a receiving groove 130 for installing a steam valve 15. The receiving groove 130 is opened at one end, And an exhaust hole 131 connected to the steam valve 15 is installed at a closed end of the receiving groove 130. [

The lid 10a has a button 16 and the cap body 10'is provided with a lever 17, an outlet valve 18 and a second receiving groove 100 for receiving the outlet valve 18, The button 16 is connected to one end of the lever 17 and the other end of the lever 17 opens the outlet valve 18 (the outlet valve 18 is closed by a compression spring and a baffle, do).

The cab body 10 'further includes a steam passage 14 and an outlet passage which is connected to the steam passage 14. One end of the steam passage 14 is connected to the outside, The pressure in the atmosphere is maintained. One end of the outlet passage is a spout and the other end is connected to the second receiving groove 100. When the outlet valve 19 is opened, water in the port body 10b flows into the second receiving groove 100, And is discharged through the outlet valve 18 from the spout.

The water in the port body 10b evaporates and the water vapor enters the steam valve 15 through the vent hole provided in the lower cover plate 12, The steam enters the steam passage 14 through the exhaust hole 131 and finally the steam reaches the thermostat in the lower portion of the liquid heating vessel 10 along the liquid heating vessel handle in the steam passage 14, Is discharged from one end connected to the outside of the steam passage (14).

When the user follows the water, when the operating member (not shown in the figure) provided on the port body 10b is pressed, the operating member presses the button 16 and the outlet valve 18 is opened through the lever 17 So that the water in the port body 10b enters into the second receiving groove 100 and flows out from the spout 141.

In the embodiments of the present invention, specific embodiments of the steam valve 15, the lid and the liquid heating container in four directions will be described.

4A to 6B, the steam valve 15 includes an exhaust pipe 151, a weight member 152, and an intake pipe 153. The exhaust pipe 151, the weight member 152, Among them, the exhaust pipe 151 has one end opened and the other end sealed, and the exhaust pipe 151 is provided with a free rotation portion in which the exhaust pipe 151 rotates along its axial direction.

The intake pipe 153 connects the exhaust pipe 151 and communicates with the exhaust pipe 151 and extends along the lateral direction of the exhaust pipe 151. The weight member 152 connects the exhaust pipe and extends along the lateral direction of the exhaust pipe 151. The weight member 152 and the intake pipe 153 are arranged such that the gravitational moment α of the circumferential direction of the exhaust pipe 151 is greater than 90 ° and smaller than or equal to 180 ° and the weight member 152 rotates around the free- The intake pipe 153 is larger than a gravity moment that rotates around the freely rotating portion.

Specifically, the exhaust pipe 151 includes a pipe body and an end plate, the upper end of the pipe body is opened, and the lower end is sealed by the end plate. The weight member 152 may be installed on the side wall of the exhaust pipe 151 and may be installed on the lower end of the exhaust pipe 151. Similarly, the intake pipe 153 may be installed on the side wall of the exhaust pipe 151 and may be installed on the lower end of the exhaust pipe 151. Naturally, for the convenience of installation, both the intake pipe 153 and the weight member 152 are provided on the side wall of the exhaust pipe 151 as an optimization example. The following description is based on the assumption that both the intake pipe 153 and the weight member 152 are provided on the side wall of the exhaust pipe 151.

An exhaust pipe 1510 is disposed on the side wall of the pipe body and an intake pipe 153 is installed at a position of the exhaust pipe 1510. The intake pipe 153 is connected to the pipe body through the exhaust pipe 1510.

The weight member 152 is installed on the side wall of the exhaust pipe 151 and the weight member 152 can be fixedly connected to the exhaust pipe 151. For example, . The weight member 152 may be detachably connected to the exhaust pipe 151. For example, the weight member 152 may be connected to the exhaust pipe 151 through a screw. The weight member 152 and the intake pipe 153 are provided in a narrow shape in the circumferential direction of the exhaust pipe 151. In addition, since the weight member 152 is relatively large in mass, a metallic member having a relatively large density such as stainless steel or copper is generally used. The exhaust pipe 151 and the intake pipe 153 may be made of plastic, or a metal member may be used.

The free rotation portion is installed in the rotation mounting portion in the lid 10a. The free rotation part may belong to a part of the pipe body such as an upper end, a middle part or a lower end part of the pipe body, the rotation installation part is a collar, and the pipe body is installed in the collar. The free rotation part may be a shaft hole provided in a closed end of the exhaust pipe 151, and the rotation installing part may be a rotation shaft installed on the lower cover plate 12 to insert a shaft hole. The free rotation portion may be a bearing that can be fitted to the side wall of the exhaust pipe 151. The rotation setting portion is a bearing hole provided in the receiving groove 130, and the bearing is fixed in the bearing hole. The free rotation part may be a rotary shaft 154 installed on the lower end surface of the exhaust pipe 151. The rotary shaft 154 is coaxial with the exhaust pipe 151 and the rotary installation part is installed on the lower cover plate 12. [ .

When the liquid heating vessel 10 is inclined, the lid 10a is inverted by 90 degrees with respect to the steady state and since the gravity moment of the weight member 152 is larger than the gravity moment of the intake pipe 153, The weight member 152 is placed at the lowermost level of the liquid level and the position of the intake pipe 153 is raised so that the weight of the liquid in the liquid heating container 10 It is difficult for water to enter the intake pipe 153.

Here, the gravity moment of the weight member 152 is M ₁ = G ₁ × L ₁ , and the gravity moment of the intake pipe 153 is M ₂ = G ₂ × L ₂ . G ₁ is the weight of the weight member 152 and L ₁ is the vertical distance between the center of the weight member 152 and the central axis of the exhaust pipe 151. G ₂ is the weight of the intake pipe 153, and L ₂ is the vertical distance between the center of the intake pipe 153 and the axial center of the exhaust pipe 151. If only M ₁ > M ₂ is satisfied, the steam valve 15 can rotate while the liquid heating vessel is inclined (inclination 90 °), the weight member 152 rotates downward, and the exhaust pipe 153 It goes up.

The weight member 152 and the intake pipe 153 have a narrow angle? In the circumferential direction of the exhaust pipe 151, where 90 deg. ≪ alpha? 180 deg. The water level in the kettle 10 becomes higher than the steam valve 15 when the kettle 10 is tilted so that the water flows into the exhaust pipe 151 along the intake pipe 153 Even if the kettle 10 is inclined, it is difficult to completely block the intake pipe 153 at the water level in the kettle 10, and when the end of the intake pipe 153 is expanded to the upper water level This is because the water is difficult to enter the exhaust pipe 151 from the intake pipe 153 and thus the overflow prevention effect is comparatively excellent.

Since the steam valve 15 is freely rotated under the driving force of the weight member 152 through the weight member 152 provided in the exhaust pipe 151 and the free rotation portion, the overflow prevention liquid heating vessel 10 The position of the intake pipe 153 is raised and the water in the liquid heating container 10 is discharged through the exhaust port 153. In this case, 1510), thereby improving the overflow preventing effect of the liquid heating vessel 10. [0054]

3, 4A, 5A and 6A, among the above embodiments, the weight member 152 and the intake pipe 153 are formed such that the narrow angle range of the exhaust pipe 151 in the circumferential direction is relatively wide, When the liquid heating vessel 10 is inclined, the water level in the liquid heating vessel 10 may be higher than the end of the intake pipe 153, and further the intake pipe 153 , The effect of preventing the overflow of the outlet valve 18 in the above embodiment is normal. In order to improve the overflow prevention effect of the outlet valve 18, the narrow angle between the expansion direction of the weight member 152 and the expansion direction of the intake pipe 153 is? ° ≤ α ≤ 180 °. Thus, even when the liquid heating vessel 10 is inclined, the end of the intake pipe 153 is not immersed in the liquid level in the liquid heating vessel 10, so that water can be introduced into the exhaust pipe 151 from the intake pipe 153 The overflow prevention effect is improved.

On the basis of the above embodiment, for the best overflow preventing effect of the steam valve 15,? = 180 占. That is, the weight member 152 and the intake pipe 153 are disposed on opposite sides of the exhaust pipe 151, respectively.

The water in the port body 10b immediately enters the lid 10a and further enters the exhaust pipe 151 through the intake pipe 153 as soon as the kettle 10 is tilted. If the rotational speed of the steam valve 15 is too slow, the exhaust pipe 153 can not wait until it is rotated to the highest position, and the water immediately enters the exhaust pipe 153 (although a relatively large amount of water And then the water in the lid 10 floods.

3, 4A and 5A, among the above embodiments, the intake pipe 153 may be a tube, a pipe, or any other shaped pipe body. Obviously, the above-mentioned several types of pipe bodies have a relatively large area in contact with air in the rotating direction and a relatively large air resistance. In this embodiment, the intake pipe 153 is provided in a flat shape. This can prevent the water from flowing into the intake pipe 153 because the intake pipe 153 can rotate to the highest position at the highest speed when the kettle 10 is tilted.

In addition, in consideration of the fact that the radius of the lid 10a is usually 5 cm to 8 cm, the length of the intake pipe 153 must also be limited. If the intake pipe 153 is too long, the intake pipe 153 may easily interfere with other structures, and the entire steam valve 15 may not rotate. If the intake pipe 153 is too short, the end of the intake pipe 153 is submerged in water after the liquid heating vessel 10 is inclined. In this embodiment, the length of the intake pipe 153 is between 3 cm and 5 cm as a relatively good embodiment.

The intake pipe 153 and the exhaust pipe 151 may be integrally formed in consideration of the fact that the connection between the intake pipe 153 and the exhaust pipe 151 is tight. In this way, air and water do not leak because the sealing position of the connection position between the two is better.

Both the intake pipe 153 and the weight member 152 may be provided at arbitrary positions on the sidewall of the exhaust pipe 151. The intake pipe 153 and the weight member 152 may have a height difference in the vertical direction and both may be on the same rotation plane . As an optimization among the embodiments, both are located in the same rotation plane. Here, when the weight member 152 is located on a different rotation plane, the weight member 152 is disposed on the upper side and the intake pipe 153 is disposed downward. For example, when the weight member 152 rotates, In this process, the exhaust pipe 151 generates a resistance against the rotation of the weight member 152, the suction force of the intake pipe 153 is reduced, This is because the rotation is delayed to the best position. When both are located on the same rotation plane, the resistance of the exhaust pipe 151 is relatively small, so that the intake pipe 153 can be quickly rotated to the highest position.

The weight member 152 is installed on the side wall of the exhaust pipe 151 and the weight member 152 can be fixedly connected to the exhaust pipe 151. For example, . The weight member 152 may also be detachably connected to the exhaust pipe 151. The exhaust pipe 151 is a plastic member, the weight member 152 is a metal member, and the weight member 152 is fixed on the exhaust pipe 151 through secondary injection. Of the relatively good embodiments, the connection type of the weight member 152 and the exhaust pipe 151 is optimized for detachable connection, for convenient installation, separation or replacement of the weight member 152. Specifically, the side wall of the exhaust pipe 151 has a protrusion 1512, and the weight member 152 is installed on the protrusion 1512. The side wall of the exhaust pipe 151 has a protrusion 1512 and has a protecting action against the exhaust pipe 151 through the connection between the protrusion 1512 and the weight member 152. If the weight member 152 is directly connected to the exhaust pipe 151 The installation of the weight member 152 may cause gas leakage or deformation of the exhaust pipe 151. [

3, 4A and 5A, in another embodiment, the weight member 152 is fan-shaped, and its centrifugal end is connected to the exhaust pipe 151. This is because, on the one hand, the fan-shaped weight member 152 is comparatively convenient to process and the cost is relatively low, and on the other hand, the fan-shaped weight member 152 has relatively small resistance at the time of rotation, This is because the intake pipe 153 can be quickly lifted.

Referring to FIGS. 2 and 8A, there are two situations when the kettle 10 is tilted. The first situation is that the kettle 10 is tilted by 90 °, and the second situation is that the kettle 10 is tilted by more than 90 ° like 180 °. When inclined by 90 DEG, the water is relatively difficult to permeate into the steam passage 14 in a relatively short time because the pressure is relatively small at the position around the exhaust pipe 151. However, when the kettle 10 is inclined by 180 DEG, the pressure is relatively large at the position around the exhaust pipe 151, so that the water seeps into the end face of the opening end of the exhaust pipe 151 in a relatively short time, As it enters the passageway 14, a leak accident may occur. In order to prevent the above situation, at least one blocking groove 1310 is formed in the end face of the closed end of the receiving groove 130, and at least one of the blocking holes 1310 is formed in the end face of the opening end of the exhaust pipe 151. [ There is a first blocking ring 154 that is inserted into the groove 1310 so that as the first blocking ring 154 is inserted into the blocking groove 1310 water flows into the steam passage 14 Can be effectively blocked. The overflow preventing effect of the steam valve 15 is improved.

Referring to FIG. 7, furthermore, when the kettle 10 is inclined, water may seep into the outer wall of the exhaust pipe 151 and enter the steam passage 14, and further leakage may occur. In order to prevent water from penetrating into the outer wall of the exhaust pipe 151, a second blocking ring 155 extending toward the inner side wall of the receiving groove 130 is formed on the side of the exhaust pipe 151 have. Here, since the exhaust pipe 151 can rotate, the exhaust pipe 151 can not interfere with the inner wall of the receiving groove 130. Therefore, if a space is left between the exhaust pipe 151 and the receiving groove 130, water can enter the steam passage 14 through the space. Therefore, by providing the second blocking ring 155, the user can prevent the kettle 10 from being damaged because the second blocking ring 155 can resist water and reduce the rate at which water enters the steam passage 14. [ It is possible to have a time margin for lifting. Of course, two, three, or more than two third blocking rings 155 may be added to further reduce the rate at which water seeps into the steam passageway 14.

In the above embodiment, when the kettle 10 is tilted by 180 degrees, since the positional pressure around the exhaust pipe 151 is relatively large, water may leak into the steam passage 14 in a relatively short time, And in a further comparative embodiment a sealing weight 156 is provided in the exhaust pipe 151 to reduce the rate at which water penetrates into the steam passage 14 or to prevent water from penetrating into the water flow passage And the sealing weight 156 moves toward the open end of the exhaust pipe 151 from the closed end of the exhaust pipe 151 when the inclination angle of the exhaust pipe 151 is greater than 90 degrees, Seal the exhaust hole (131) of the closed end.

Referring to FIG. 6A, it is considered that, based on the above embodiment, the seal weight 156 can not block the exhaust pipe 151, and the exhaust of the exhaust pipe 151 is not smooth. Therefore, in this embodiment, an air guide mechanism is provided on the inner wall of the exhaust pipe 151, and the air guide mechanism has an air guide passage formed between the sealing weight 156 and the inner wall of the exhaust pipe 151. Here, the air guide mechanism may be a protrusion such as a circular protrusion or a rib 1511 provided on the inner wall of the exhaust pipe 151, or may be a flow guide groove provided on the inner wall of the exhaust pipe. Here, the air guide mechanism is a plurality of ribs 1511 that optimally extend along the exhaust pipe axis direction and are distributed along the circumferential direction of the exhaust pipe, and the air guide passage is formed between adjacent ribs 1511 .

Among the above embodiments, the sealing weight 156 may have various shapes, and it is only necessary to cover the exhaust hole 131 when the kettle is inclined. For example, the sealing weight 156 may be columnar or ball-shaped so that the movement resistance of the sealing weight 156 in the exhaust pipe 151 is relatively small, thereby making the movement more smooth.

In order to improve the hermeticity between the upper end of the exhaust pipe 151 and the periphery of the exhaust hole 131, an elastic member (not shown) is inserted between the lower cover plate 12 and the end face of the closed end of the exhaust pipe 151 The elastic member 159 is installed to surround the rotating shaft 157 installed on the lower end surface of the exhaust pipe 151. This allows the elastic member 159 to quickly float up the exhaust pipe 151 to seal the upper end of the exhaust pipe 151 with the periphery of the exhaust hole 131 when the kettle 10 is inclined so that the steam valve 15 ) Overflow prevention effect. Here, the elastic member 159 may be a spring, a rubber pad, or a clip. Of course, the optimization of the elastic member 159 is a spring.

Referring to FIG. 6A, it has been considered that, based on the above embodiment, when the elastic member 159 is subjected to a long period of pressure, the elastic function of the elastic member 159 may be reduced or become ineffective. In the present embodiment, the exhaust pipe 151 has a sleeve 158 extending from the end face of the closed end, and the sleeve 158 is installed to surround the elastic member 159. In this way, even if the elastic member 159 undergoes an excessive pressure, the elastic member 159 undergoes permanent deformation under the supporting action of the sleeve 158.

In the above description, the improvement of the steam valve 15 and the lid 10 has been mainly described, and the following is a specific introduction to the combination of the lid 10a and the port body 10b.

2 and 3, the lid 10a is installed in the port body 10b, the upper end of the port body 10b is opened, and the lid 10a seals the open end of the port body 10b. In a relatively good embodiment, there is a sealing ring 19 between the lower cover plate 12 and the port body 10b, and the lid 10a is hermetically connected to the inner wall of the port body 10b through a sealing ring 19. [ In addition, in order to ensure the connection strength between the lid 10a and the port body 10b, the lid 10a and the port body 10b are connected via a snap structure, and the snap structure is provided on the lid 10a And includes a flexible latch and a slot provided on the inner wall of the port body 10b. When the lid 10a is installed in the port body 10b, the latch is deformed under pressure, and when the latch enters the slot, as the latch recovers the deformation and further matches the slot, 10b.

In the second aspect, all of the above embodiments do not take into account the frictional force when the exhaust pipe 151 rotates. Therefore, the following description relates to the embodiment in which the exhaust pipe 151 receives a frictional force when the steam valve 15 rotates Introduction.

The steam valve 15 includes an exhaust pipe 151, a weight member 152 and an intake pipe 153. Among them, the exhaust pipe 151 has one end opened and the other end sealed, and the exhaust pipe 151 is provided with a free rotation portion in which the exhaust pipe 151 rotates along its axial direction.

The intake pipe 153 connects the exhaust pipe 151 and communicates with the exhaust pipe 151 and extends along the lateral direction of the exhaust pipe 151. The weight member 152 connects the exhaust pipe 151 and extends along the lateral direction of the exhaust pipe 151. The weight member 152 and the intake pipe 153 are arranged such that the narrowing angle alpha in the circumferential direction of the exhaust pipe 151 is greater than 90 degrees and less than or equal to 180 degrees and in which the weight member 152 has a gravity moment Is greater than the sum of the gravitational moment that the intake pipe (153) surrounds the free rotation portion and the moment of friction when the exhaust pipe (151) rotates.

Specifically, the exhaust pipe 151 includes a pipe body and an end plate, the upper end of the pipe body is opened, and the lower end is sealed by the end plate. The weight member 152 may be installed on the side wall of the exhaust pipe 151 and may be installed on the lower end of the exhaust pipe 151. Similarly, the intake pipe 153 may be installed on the side wall of the exhaust pipe 151 and may be installed on the lower end of the exhaust pipe 151. Naturally, for the convenience of installation, both the intake pipe 153 and the weight member 152 are provided on the side wall of the exhaust pipe 151 as an optimization example. The following description is based on the assumption that both the intake pipe 153 and the weight member 152 are provided on the side wall of the exhaust pipe 151.

An exhaust pipe 1510 is disposed on the side wall of the pipe body and an intake pipe 153 is installed at a position of the exhaust pipe 1510. The intake pipe 153 is connected to the pipe body through the exhaust pipe 1510.

The weight member 152 is installed on the side wall of the exhaust pipe 151 and the weight member 152 can be fixedly connected to the exhaust pipe 151. For example, . The weight member 152 may be detachably connected to the exhaust pipe 151. For example, the weight member 152 may be connected to the exhaust pipe 151 through a screw. The weight member 152 and the intake pipe 153 are provided in a narrow shape in the circumferential direction of the exhaust pipe 151. In addition, since the weight member 152 is relatively large in mass, a metallic member having a relatively large density such as stainless steel or copper is generally used. The exhaust pipe 151 and the intake pipe 153 can be made of plastic and can be made of a metal member. However, the stainless steel material such as SUS304 is optimized by considering the hygiene, the heat resistance, the steam resistance, to be.

The free rotation portion is installed in the rotation mounting portion in the lid 10a. The free rotation portion may belong to a part of the pipe body such as an upper end portion, a middle portion or a lower end portion of the pipe body, and the rotation setting portion is a collar, and the pipe body is installed in the collar. The free rotation part may be a first rotation shaft 157 installed on the lower end surface of the exhaust pipe 151. The first rotation shaft 157 is coaxial with the exhaust pipe 151, And is a first shaft hole to be installed. The free rotation part may be a second shaft hole (blind hole) provided in the closed end of the exhaust pipe 151, and the rotation setting part is a second rotation shaft installed on the lower cover plate 12 and inserted into the shaft hole. The free rotation part may be a rotation shaft provided on a side wall of the exhaust pipe 151. The rotation installation part is a bearing hole provided in the receiving groove 130, and the bearing is fixed in the bearing hole.

When the liquid heating vessel 10 is inclined, the lid 10a is inverted by 90 degrees with respect to the steady state and since the gravity moment of the weight member 152 is larger than the gravity moment of the intake pipe 153, And the position of the intake pipe 153 is raised so that the pressure in the liquid heating container 10 is lowered to the lower end of the liquid heating container 10, It is difficult for water to enter the intake pipe 153.

Here, the gravity moment of the weight member 152 is M ₁ = G ₁ × L ₁ , the gravity moment of the intake pipe 153 is M ₂ = G ₂ × L _2, and the gravity moment of the weight member 152 when the exhaust pipe 151 rotates The frictional force moment is M ₃ = f x d ₁ . G ₁ is the weight of the weight member 152 and L ₁ is the vertical distance between the center of the weight member 152 and the central axis of the exhaust pipe 151. G ₂ is the weight of the intake pipe 153, L ₂ is the vertical distance between the center of the intake pipe 153 and the axial center of the exhaust pipe 151, f is the frictional force received when the exhaust pipe rotates 151) and the inner wall of the receiving groove 130, or the frictional force between the free rotation portion and the rotary mounting portion), and d ₁ is the radius of the exhaust pipe. If only M ₁ > M ₂ + M ₃ is satisfied, the steam valve 15 can rotate when the liquid heating vessel is inclined (inclination of 90 °), the weight member 152 rotates downward, 153).

The weight member 152 and the intake pipe 153 have a narrow angle? In the circumferential direction of the exhaust pipe 151, where 90 deg. ≪ alpha? 180 deg. The water level in the kettle 10 becomes higher than the steam valve 15 so that the water flows along the intake pipe 153 to the inside of the exhaust pipe 151. In other words, Even if the kettle 10 is inclined, it is difficult to completely block the intake pipe 153 at the water level in the kettle 10, and when the end of the intake pipe 153 is positioned above the water level It is difficult for the water to enter the exhaust pipe 151 from the intake pipe 153, so that the overflow prevention effect is comparatively excellent.

Since the volume of the lid 10 is limited, the mass of the weight member 152 should not be excessively large. Otherwise, the volume occupied by the inside of the lid 10 is relatively large, and it is likely to interfere with other structures. The mass of the weight member 152 should also not be too small. Otherwise, when the kettle 10 is inclined, the rotation of the steam valve 15 is comparatively slow, and the overflow prevention effect is normal. Therefore, in view of the above situation, in this embodiment, the mass m1 of the weight member 152 is greater than or equal to 10 g and less than or equal to 50 g. By doing so, the space occupation rate of the weight member 152 can be relatively low and the rotational response speed of the steam valve 15 can be made faster. In addition, the mass of the intake pipe 153 should be equal to or greater than 5 g and equal to or less than 20 g.

Kettle 10 is a surface inclined, to ensure the normal rotation of the steam valve 15, the weight of the weight member 152 is G1, the weight of the intake pipe 153 is _{G 2, G 1 / G 2} ∈ [0.5 , 12]. Furthermore, if the ratio of G ₁ and G ₂ is too small, the axial distance between the center of the weight member 152 and the exhaust pipe 151 should be increased, considering that the diameter of the lid is usually small, usually within 10 cm to 15 cm do. In this case, M ₁ > M ₂ + M ₃ can be satisfied, and the steam valve 15 can be normally rotated. Among the relatively good embodiments, G ₁ / G ₂ ∈ [1,10].

The interval L ₁ between the center of the weight member 150 and the axis of the exhaust pipe 151 and the interval L ₂ between the center of the intake pipe 153 and the axis of the exhaust pipe 151 are relatively L ₁ should be larger than L _{2 in} order to allow the steam valve 15 to rotate more smoothly under a general condition. However, since it is considered that the exhaust pipe 151 itself receives frictional resistance, The position of the intake pipe 153 is adjusted in order to ensure that the motor 15 can rotate quickly after the kettle 10 is tilted, where L ₁ / L ₂ ∈ [2,20]. Of course, considering the internal size of the kettle 10, the optimization range of L ₁ / L ₂ is [4, 15].

In the above embodiment, the weight member 152 and the intake pipe 153 are relatively wide in the circumferential direction alpha range of the exhaust pipe 151, and are 90 DEG < alpha ≤ 180 DEG. When the liquid heating vessel 10 is inclined, the water level in the liquid heating vessel 10 can be higher than the end of the intake pipe 153, and further, the water can be introduced into the exhaust pipe 151 from the end of the intake pipe 153 The effect of preventing the overflow of the outlet valve 18 in the above embodiment is normal. 3, 4A, and 6A, in order to improve the overflow preventing effect of the outlet valve 18 among the comparatively good examples, the extension direction of the weight member 152 and the expansion direction of the intake pipe 153 , And 170 deg.??? 180 deg., Respectively. Thus, even if the liquid heating vessel 10 is inclined, it is difficult for the distal end of the intake pipe 153 to be immersed in the liquid level in the liquid heating vessel 10, so that water is sucked from the intake pipe 153 into the exhaust pipe 151 The overflow prevention effect is enhanced.

The weight member 152 and the intake pipe 153 are provided on the opposite sides of the exhaust pipe 151 so as to face each other, Are disposed on both sides.

As soon as the kettle 10 falls, the water in the port body 10b immediately enters the lid 10a and further into the exhaust pipe 151 from the intake pipe 153. [ If the rotation speed of the steam valve 15 is too slow, the exhaust pipe 153 can not wait until it is rotated to its maximum position, and the water immediately enters the exhaust pipe 153 (even if there is a relatively large difference And then the water in the lid 10 is flooded.

Referring to FIGS. 3 and 4A, in this embodiment, the intake pipe 153 may be a tube, may be an individual pipe, or may be a pipe body of other shapes. Obviously, the above-mentioned several types of pipe bodies have a relatively large area in contact with air in the rotating direction and a relatively large air resistance. In this embodiment, the intake pipe 153 is provided in a flat shape. This can prevent the water from flowing into the intake pipe 153 because the intake pipe 153 can rotate to the highest position at the highest speed when the kettle 10 is tilted.

Further, in consideration of the fact that the radius of the lid 10a is usually 5 cm to 8 cm, the length of the intake pipe 153 must also be limited. If the intake pipe 153 is too long, the intake pipe 153 may easily interfere with other structures, and the entire steam valve 15 may not rotate. If the intake pipe 153 is too short, when the liquid heating container 10 is inclined, the end of the intake pipe 153 is immersed in water. In this embodiment, the length of the intake pipe 153 is between 3 cm and 5 cm as a relatively good embodiment.

The intake pipe 153 and the exhaust pipe 151 may be integrally formed in consideration of the fact that the connection between the intake pipe 153 and the exhaust pipe 151 is tight. In this way, air and water do not leak because the sealing position of the connection position between the two is better.

Both the intake pipe 153 and the weight member 152 may be provided at arbitrary positions on the sidewall of the exhaust pipe 151. The intake pipe 153 and the weight member 152 may have a height difference in the vertical direction and both may be on the same rotation plane . As an optimization among the embodiments, both are located in the same rotation plane. When the weight member 152 is located on a different plane of rotation, the weight member 152 is disposed on the upper side and the intake tube 153 is disposed downward. For example, when the weight member 152 rotates, The weight 151 of the weight member 152 must transmit the gravity moment of the weight member 152 to the intake pipe 153. In this process, as the exhaust pipe 151 causes a resistance against the rotation of the weight member 152, 153) rotation to the best position. When both are located on the same rotation plane, the resistance of the exhaust pipe 151 is relatively small, so that the intake pipe 153 can be quickly rotated to the highest position.

The weight member 152 is installed on the side wall of the exhaust pipe 151 and the weight member 152 can be fixedly connected to the exhaust pipe 151. For example, . The weight member 152 may also be detachably connected to the exhaust pipe 151. The exhaust pipe 151 is a plastic member, the weight member 152 is a metal member, and the weight member 152 is fixed on the exhaust pipe 151 through secondary injection. Of the relatively good embodiments, the connection type of the weight member 152 and the exhaust pipe 151 is optimized for the detachable connection, for convenient installation, disconnection or replacement of the weight member 152. Specifically, a projection 1512 is provided on the side wall of the exhaust pipe 151, and a weight member 152 is provided on the projection 1512. The side wall of the exhaust pipe 151 has a protrusion 1512 and has a protecting action against the exhaust pipe 151 through the connection between the protrusion 1512 and the weight member 152. If the weight member 152 is directly connected to the exhaust pipe 151 The installation of the weight member 152 may cause gas leakage or deformation of the exhaust pipe 151. [

3 and 4A, in another embodiment, the weight member 152 is fan-shaped, and its centrifugal end is connected to the exhaust pipe 151. This is because, on the one hand, the fan-shaped weight member 152 is comparatively convenient to process and has a relatively low cost, and on the other hand, the fan-shaped weight member 152 has relatively small resistance at the time of rotation, Since the engine 153 can be quickly lifted.

Referring to FIGS. 2 and 8A, there are two situations when the kettle 10 is tilted. The first situation is that the kettle 10 is tilted by 90 °, and the second situation is that the kettle 10 is tilted by more than 90 ° like 180 °. When inclined by 90 DEG, the water is relatively difficult to permeate into the steam passage 14 in a relatively short time because the pressure is relatively small at the position around the exhaust pipe 151. However, when the kettle 10 is inclined by 180 DEG, the pressure is relatively large at the position around the exhaust pipe 151, so that the water seeps into the end face of the opening end of the exhaust pipe 151 in a relatively short time, Leakage may occur as it enters the passageway 14. In order to prevent the above situation, at least one blocking groove 1310 is formed in the end face of the sealing end of the receiving groove 130, and at least one blocking groove 1310 is formed in the end face of the opening end of the exhaust pipe 151 The first blocking ring 154 is inserted into the blocking groove 1310 so that water can be effectively prevented from penetrating into the steam passage 14 have. The overflow preventing effect of the steam valve 15 is improved.

Referring to FIG. 7, furthermore, when the kettle 10 is inclined, water may seep into the outer wall of the exhaust pipe 151 and enter the steam passage 14, and further leakage may occur. In the embodiment, there is a second blocking ring 155 on the side of the exhaust pipe 151 that extends toward the inner side wall of at least one receiving groove 130 to prevent water from penetrating into the outer wall of the exhaust pipe 151. Here, since the exhaust pipe 151 can rotate, no interference can occur between the exhaust pipe 151 and the inner wall of the receiving groove 130. Therefore, if a space is left between the exhaust pipe 151 and the receiving groove 130, since water can enter the steam passage 14 through the space, if the second blocking ring 155 is installed, The user can have a time margin to lift the kettle 10 because the blocking ring 155 can resist water and reduce the rate at which water enters the steam passage 14. [ Of course, two, three, or more than two third blocking rings 155 may be added to further reduce the rate at which water seeps into the steam passageway 14.

In the above embodiment, when the kettle 10 is tilted by 180 °, the positional pressure around the exhaust pipe 151 is comparatively large, so that water may leak into the steam passage 14 in a relatively short time, And in another comparative embodiment there is a seal weight 156 in the exhaust pipe 151 to reduce the rate at which the water penetrates into the steam passage 14 or to prevent water from penetrating into the water flow passage, The seal weight 156 moves toward the open end of the exhaust pipe 151 from the closed end of the exhaust pipe 151 and reaches the exhaust port 131 of the closed end of the receiving groove 130 when the inclination angle of the exhaust pipe 151 is greater than 90 degrees ).

Referring to Fig. 6A, it is considered that, based on the above embodiment, the sealing weight 156 can not block the exhaust pipe 151, and the exhaust of the exhaust pipe 151 is not smooth. Therefore, in this embodiment, an air guide mechanism is provided on the inner wall of the exhaust pipe 151, and an air guide passage is formed between the sealing weight 156 and the inner wall of the exhaust pipe 151. Here, the air guide mechanism may be a protrusion such as a circular protrusion or a rib 1511 provided on the inner wall of the exhaust pipe 151, or may be a flow guide groove provided on the inner wall of the exhaust pipe. Here, the air guide mechanism is optimally a plurality of ribs 1511 extending along the exhaust pipe circumferential direction and extending along the exhaust pipe circumferential direction, and an air guide passage is formed between adjacent ribs 1511.

Among the above embodiments, the sealing weight 156 may have various shapes, and it is only necessary to cover the exhaust hole 131 when the kettle is inclined. For example, the sealing weight 156 may be columnar or ball-shaped so that the movement resistance of the sealing weight 156 in the exhaust pipe 151 is relatively small, which makes the movement more smooth.

An elastic member 159 is provided between the end face of the closed end of the lower cover plate 12 and the exhaust pipe 151 in order to improve the hermeticity between the upper end of the exhaust pipe 151 and the periphery of the exhaust hole 131. [ And the elastic member 159 is installed so as to surround the rotating shaft 157 provided on the lower end surface of the exhaust pipe 151. The rotating shaft 157 is used as an example of the rotating mounting portion. This allows the elastic member 159 to quickly float up the exhaust pipe 151 to seal the upper end of the exhaust pipe 151 with the periphery of the exhaust hole 131 when the kettle 10 is inclined so that the steam valve 15 ) Overflow prevention effect. Here, the elastic member 159 may be a spring, a rubber pad, or a clip. Of course, the optimization of the elastic member 159 is a stainless spring.

When the spring is installed, the upper end of the exhaust pipe 151 can be sealed with the periphery of the exhaust hole 131, but at the same time, the friction moment at which the exhaust pipe 151 rotates and rotates also increases. Here, since the spring comes in contact with the lower end of the exhaust pipe 151, the main frictional force received by the exhaust pipe 151 comes from the spring.

Therefore, the spring can not be subjected to too tight a pressure of the exhaust pipe 151, or the spring is too large in frictional force with respect to the exhaust pipe 151 when the kettle 10 is inclined, 12 is too large, the steam valve 15 can not rotate smoothly. Based on the parameters of the weight member 152 and the intake pipe 153, the inner diameter of the spring is D? [10 mm, 20 mm], the total number of turns is n? [4,12] [10g / mm, 40g / mm] and the mass is m3∈ [0.3g, 1.5g]. In this way, the normal rotation of the steam valve 15 can be ensured.

Referring to FIG. 6A, it has been considered that, based on the above embodiment, when the elastic member 159 is subjected to a long period of pressure, the elastic function of the elastic member 159 may be reduced or become ineffective. In the present embodiment, the exhaust pipe 151 has a sleeve 158 extending from the end face of the closed end thereof, and the sleeve 158 is installed to surround the elastic member 159. In this way, even if the elastic member 159 undergoes an excessive pressure, the elastic member 159 undergoes permanent deformation under the supporting action of the sleeve 158.

In the above description, the improvement of the steam valve 15 and the lid 10 has been mainly described, and the following is a specific introduction to the combination of the lid 10a and the port body 10b.

2 and 3, the lid 10a is installed in the port body 10b, the upper end of the port body 10b is opened, and the lid 10a seals the open end of the port body 10b . A sealing ring 19 is provided between the lower cover plate 12 and the port body 10b and the lid 10a is hermetically connected to the inner wall of the port body 10b through the sealing ring 19. [ In addition, in order to ensure the connection strength between the lid 10a and the port body 10b, the lid 10a and the port body 10b are connected via a snap structure, and the snap structure is provided on the lid 10a And includes a flexible latch and a slot provided on the inner wall of the port body 10b. When the lid 10a is installed in the port body 10b, the latch is deformed under pressure and when the latch enters the slot, the lid recovers the deformation and further matches the slot, 10b.

In the third aspect, in order to further improve the effect of preventing the overflow, based on the fact that the steam valve can freely rotate, in the present embodiment, the steam valve 15 has the exhaust pipe 151, the weight member 152 And an intake pipe (153). The exhaust pipe 151 has one end opened and the other end sealed, the outer surface of the exhaust pipe 151 has a watertight structure, and the watertight structure has at least a first block (not shown) installed on the outer wall of the exhaust pipe 151, And a second blocking ring 155 provided on the end face of the opening of the ring 154 and / or the exhaust pipe 151. On the exhaust pipe 151, there is provided a free passage 151 for allowing the exhaust pipe 151 to rotate around its axial direction There is a rotating part.

The intake pipe 153 connects the exhaust pipe 151 and communicates with the exhaust pipe 151 and extends along the lateral direction of the exhaust pipe 151. The weight member 152 connects the exhaust pipe 151 and extends along the lateral direction of the exhaust pipe 151. The weight member 152 and the intake pipe 153 are connected to each other by a gravitational moment α that is larger than 90 ° and smaller than or equal to 180 ° in the circumferential direction of the exhaust pipe 151 and that the weight member 152 rotates around the free- The intake pipe 153 is larger than the gravity moment which rotates around the free rotation portion.

Specifically, the exhaust pipe 151 includes a pipe body and an end plate, the upper end of the pipe body is opened, and the lower end is sealed by the end plate. The weight member 152 may be installed on the side wall of the exhaust pipe 151 and may be installed on the lower end of the exhaust pipe 151. Similarly, the intake pipe 153 may be installed on the side wall of the exhaust pipe 151 and may be installed on the lower end of the exhaust pipe 151. Of course, for the convenience of installation, the optimum embodiment is to install both the intake pipe 153 and the weight member 152 on the side wall of the exhaust pipe 151. The following description is based on the assumption that both the intake pipe 153 and the weight member 152 are provided on the side wall of the exhaust pipe 151.

An exhaust pipe 1510 is disposed on the side wall of the pipe body and an intake pipe 153 is installed at a position of the exhaust pipe 1510. The intake pipe 153 is connected to the pipe body through the exhaust pipe 1510.

The weight member 152 is installed on the side wall of the exhaust pipe 151 and the weight member 152 can be fixedly connected to the exhaust pipe 151. For example, . The weight member 152 may be detachably connected to the exhaust pipe 151. For example, the weight member 152 may be connected to the exhaust pipe 151 through a screw. The weight member 152 and the intake pipe 153 are provided in a narrow shape in the circumferential direction of the exhaust pipe 151. In addition, since the weight member 152 is relatively large in mass, a metal member, which is generally made of a material having relatively high density such as stainless steel or copper, is used. The exhaust pipe 151 and the intake pipe 153 may be made of plastic, or a metal member may be used.

The free rotation portion is installed in the rotation mounting portion in the lid 10a. The free rotation portion may belong to a part of the pipe body such as an upper end portion, a middle portion or a lower end portion of the pipe body, and the rotation setting portion is a collar, and the pipe body is installed in the collar. The free rotation part may be a first rotation shaft 157 installed on the lower end surface of the exhaust pipe 151. The first rotation shaft 157 is coaxial with the exhaust pipe 151, And is a first shaft hole to be installed. The free rotation part may be a second shaft hole (blind hole) provided in the closed end of the exhaust pipe 151, and the rotation setting part is a second rotation shaft installed on the lower cover plate 12 and inserted into the shaft hole. The free rotation part may be a rotation shaft provided on the side wall of the exhaust pipe 151. The rotation installation part is a bearing hole provided in the receiving groove 130, and the bearing is fixed in the bearing hole.

The lid 10a is inverted by 90 degrees with respect to the steady state and the gravity moment of the weight member 152 is larger than the gravity moment of the intake pipe 153 so that the operation of the weight member 152 And the position of the intake pipe 153 is increased so that the water in the liquid heating container 10 is discharged to the bottom of the liquid heating container 10, It is difficult to enter the intake pipe 153.

Here, the gravity moment of the weight member 152 is M ₁ = G ₁ × L ₁ , the gravity moment of the intake pipe 153 is M ₂ = G ₂ × L ₂ , G ₁ is the weight of the weight member 152 L ₁ is the vertical distance between the center of the weight member 152 and the axial center of the exhaust pipe 151. G ₂ is the weight of the intake pipe 153, and L ₂ is the vertical distance between the center of the intake pipe 153 and the axial center of the exhaust pipe 151. Here, M _1> M ₂ If only satisfied when the liquid heating vessel slanted (slope 90 °) the steam valve 15 is capable of rotation, and rotation down to the weight member 152, the exhaust pipe 153 is It goes up.

The weight member 152 and the intake pipe 153 have a narrow angle? In the circumferential direction of the exhaust pipe 151, where 90 deg. ≪ alpha? 180 deg. This is because the water level in the kettle 10 is higher than the steam valve 15 after the kettle 10 is tilted so that the water flows along the intake pipe 153 to the inside of the exhaust pipe 151 Even if the kettle 10 is inclined, it is difficult to completely block the intake pipe 153 at the water level in the kettle 10, and when the end of the intake pipe 153 is positioned above the water level It is difficult for the water to easily enter the exhaust pipe 151 from the intake pipe 153, and the overflow prevention effect is comparatively excellent.

In addition, the first blocking ring 154 and the second blocking ring 155 are convexly provided on the outer surface of the exhaust pipe 151. Whether the first blocking ring 154 or the second blocking ring 155 is installed It is possible to effectively prevent the water from seeping into the steam passage 14 between the steam valve 15 and the receiving groove 130 when the kettle is tilted. The first blocking ring 154 and the second blocking ring 155 may be connected and may not be connected.

Among the relatively excellent embodiments, the first blocking rings 154 are numerous and arranged in order along the axial direction of the exhaust pipe 151. [ When the steam valve 15 is installed on the lid 10a, the side wall surface contact area of the receiving groove 130 with the side surface of the exhaust pipe 151 is reduced due to the presence of the first blocking ring 154 The interference force between the exhaust pipe 151 and the wall surface of the receiving groove 130 is reduced and the rotational resistance of the steam valve 15 is reduced when the exhaust pipe 151 rotates. Likewise, considering the rotation of the steam valve 15, the number of the second blocking rings 155 is plural and is arranged along the radial direction of the exhaust pipe 151, so that the resistance of the rotation of the steam valve 15 is reduced .

In addition, when the kettle 10 is inclined, water enters between the exhaust pipe 151 and the sidewall surface of the receiving groove 130 because of the presence of the first blocking ring 154 and / or the second blocking ring 155 to be. Thus, if the groove between the first blocking ring 154 and / or the second blocking ring 155 is to be completely submerged in water, the water will overflow the first blocking ring 154 and / or the second blocking ring 155 The overflow prevention effect is improved.

In order to further improve the overflow preventing effect of the steam valve 15 among other comparatively good examples, the sum of the volume of the closed space formed between the watertight mechanism and the inner wall of the receiving groove 130 is V ₀ , and the exhaust pipe 151 ) And the side wall surface of the receiving groove 130 is V ₁ , and V ₀ / V ₁ ∈ [0.5, 0.95]. Here, the occupied volume of the first blocking ring 154 and / or the second blocking ring 155 is V ₂ , and V ₁ = V ₂ + V ₀ . Since the steam valve 15 can rotate in the receiving groove 130, there is a certain space between the side wall surface of the receiving groove 130 and the side surface of the exhaust pipe 151, so that a relatively large interference Can be prevented. Here, when the value of V ₀ / V ₁ is close to 0.5, that is, the sum of the volumes of the first blocking ring 154 and / or the second blocking ring 155 occupies about 50% of the space remaining in the receiving groove The space between the sidewall surface of the receiving groove 130 and the side surface of the exhaust pipe 151 is relatively large and the rotating effect of the steam valve 15 is relatively excellent. However, the water blocking effect of the first blocking ring 154 and / or the second blocking ring 155 is relatively reduced. If the value of V ₀ / V ₁ approaches 0.95, that is, the volume of the first blocking ring 154 and / or the second blocking ring 155 occupies 5% of the remaining space of the entire receiving groove 130, The space between the side wall surface of the groove 130 and the surface of the exhaust pipe 151 side is relatively relatively small and the rotational resistance of the steam valve 15 is increased. However, the water blocking effect of the first blocking ring 154 and / or the second blocking ring 155 is relatively strengthened. Here, the value of V ₀ / V ₁ can take 0.6, 0.7, 0.8, 0.9, etc., and of course, if the steam valve 15 is rotated more smoothly, the first blocking ring 154 and / The water blocking effect of the ring 155 is also relatively good, and the optimization of the value of V ₀ / V ₁ is 0.75 to 0.85.

3, 4B and 6B, among the above embodiments, the weight member 152 and the intake pipe 153 are formed such that the narrow angle range of the exhaust pipe 151 in the circumferential direction is relatively wide, The water level in the kettle 10 may be higher than the end of the intake pipe 153 and further the intake pipe 153 may be connected to the intake pipe 153. In this case, The effect of preventing the overflow of the outlet valve 18 in the above embodiment is common. In order to improve the overflow preventing effect of the outlet valve 18, among the comparatively good examples, the narrow angle between the expansion direction of the weight member 152 and the expansion direction of the intake pipe 153 is?, 170? alpha ≤ 180 DEG. This makes it difficult for the distal end of the intake pipe 153 to be immersed in the water level in the kettle 10 even if the kettle 10 is inclined and therefore water can not enter the exhaust pipe 151 from the intake pipe 153, The overflow prevention effect is enhanced.

The weight member 152 and the intake pipe 153 are located on the opposite sides of the exhaust pipe 151 in the circumferential direction of the exhaust pipe 151. In order to prevent the overflow of the steam valve 15, Are disposed on both sides.

The water in the port body 10b immediately enters the lid 10a and further enters the exhaust pipe 151 through the intake pipe 153 as soon as the kettle 10 is tilted. If the rotation speed of the steam valve 15 is too slow, the exhaust pipe 153 can not wait until it is rotated to its maximum position, and the water immediately enters the exhaust pipe 153 (even if there is a relatively large difference And then the water in the lid 10 is flooded.

3, 4A, and 4B, among the above embodiments, the intake pipe 153 may be a tube, a pipe, or other shaped pipe body. Obviously, the above-mentioned several types of pipe bodies have a relatively large area in contact with air in the rotating direction and a relatively large air resistance. In this embodiment, the intake pipe 153 is provided in a flat shape. When the kettle 10 is inclined, water can be prevented from flowing into the intake pipe 153 because the intake pipe 153 can rotate to the highest position at the highest speed.

In addition, in consideration of the fact that the radius of the lid 10a is usually 5 cm to 8 cm, the length of the intake pipe 153 must also be limited. If the intake pipe 153 is too long, the intake pipe 153 may easily interfere with other structures, and the entire steam valve 15 may not rotate. If the intake pipe 153 is too short, the end of the intake pipe 153 is submerged in water after the liquid heating vessel 10 is inclined. In this embodiment, the length of the intake pipe 153 is between 3 cm and 5 cm as a relatively good embodiment.

The intake pipe 153 and the exhaust pipe 151 may be integrally formed in consideration of the fact that the connection between the intake pipe 153 and the exhaust pipe 151 is tight. In this way, the airtightness of the connecting position between the two is better, and no air or water leaks.

Both the intake pipe 153 and the weight member 152 may be provided at arbitrary positions on the sidewall of the exhaust pipe 151. The intake pipe 153 and the weight member 152 may have a height difference in the vertical direction and both may be on the same rotation plane . As an optimization among the embodiments, both are located in the same rotation plane. Here, when the weight member 152 is located on a different rotation plane, the weight member 152 is disposed on the upper side and the intake pipe 153 is disposed downward. For example, when the weight member 152 rotates, In this process, the exhaust pipe 151 generates a resistance against the rotation of the weight member 152, the suction force of the intake pipe 153 is reduced, This is because the rotation is delayed to the best position. When both are located on the same rotation plane, the resistance of the exhaust pipe 151 is relatively small, so that the intake pipe 153 can be quickly rotated to the highest position.

The weight member 152 is installed on the side wall of the exhaust pipe 151 and the weight member 152 can be fixedly connected to the exhaust pipe 151. For example, . The weight member 152 may also be detachably connected to the exhaust pipe 151. The exhaust pipe 151 is a plastic member, the weight member 152 is a metal member, and the weight member 152 is fixed on the exhaust pipe 151 through secondary injection. Of the relatively good embodiments, the connection type of the weight member 152 and the exhaust pipe 151 is optimized for detachable connection, for convenient installation, separation or replacement of the weight member 152. Specifically, a projection 1512 is provided on the side wall of the exhaust pipe 151, and a weight member 152 is provided on the projection 1512. The side wall of the exhaust pipe 151 has a protrusion 1512 and has a protecting action against the exhaust pipe 151 through the connection between the protrusion 1512 and the weight member 152. If the weight member 152 is directly connected to the exhaust pipe 151 The installation of the weight member 152 may cause gas leakage or deformation of the exhaust pipe 151. [

3 and 4B, in another embodiment, the weight member 152 is fan-shaped, and its centrifugal end is connected to the exhaust pipe 151. This is because, on the one hand, the fan-shaped weight member 152 is comparatively convenient to process and has a relatively low cost, and on the other hand, the fan-shaped weight member 152 has relatively small resistance at the time of rotation, Since the engine 153 can be quickly lifted.

Referring to FIGS. 2 and 8B, there are two situations when the kettle 10 is tilted. The first situation is that the kettle 10 is tilted by 90 °, and the second situation is that the kettle 10 is tilted by more than 90 ° like 180 °. When inclined by 90 DEG, the water is relatively difficult to permeate into the steam passage 14 in a relatively short time because the pressure is relatively small at the position around the exhaust pipe 151. However, when the kettle 10 is inclined by 180 DEG, the pressure is relatively large at the position around the exhaust pipe 151, so that the water seeps into the end face of the opening end of the exhaust pipe 151 in a relatively short time, Leakage may occur as it enters the passageway 14. In order to prevent the above situation, at least one blocking groove 1310 is formed in the end face of the sealing end of the receiving groove 130, and at least one blocking groove 1310 is formed in the end face of the opening end of the exhaust pipe 151 The second blocking ring 155 is inserted into the blocking groove 1310 to effectively prevent water from penetrating into the steam passage 14 have. The overflow preventing effect of the steam valve 15 is improved.

In the above embodiment, when the kettle 10 is tilted by 180 °, the positional pressure around the exhaust pipe 151 is relatively large, so that the water seeps into the steam passage 14 in a relatively short time to cause a leakage accident In another comparative embodiment there is a seal weight 156 in the exhaust pipe 151 to reduce the rate at which the water penetrates into the steam passage 14 or to prevent water from penetrating into the water flow passage, The weights 156 move toward the open end of the exhaust pipe 151 from the closed end of the exhaust pipe 151 when the inclination angle of the exhaust pipe 151 is greater than 90 degrees and are directed to the exhaust hole 131 of the closed end of the receiving groove 130, Lt; / RTI >

Referring to FIG. 6B, it is considered that, based on the above embodiment, the sealing weight 156 can not block the exhaust pipe 151, and the exhaust of the exhaust pipe 151 is not smooth. Therefore, in this embodiment, an air guide mechanism is provided on the inner wall of the exhaust pipe 151, and an air guide passage is formed between the sealing weight 156 and the inner wall of the exhaust pipe 151. Here, the air guide mechanism may be a protrusion such as a circular protrusion or a rib 1511 provided on the inner wall of the exhaust pipe 151, or may be a flow guide groove provided on the inner wall of the exhaust pipe. Here, the air guide mechanism is optimally a plurality of ribs 1511 extending along the exhaust pipe circumferential direction and extending along the exhaust pipe circumferential direction, and an air guide passage is formed between adjacent ribs 1511.

Among the above embodiments, the sealing weight 156 may have various shapes, and it is only necessary to cover the exhaust hole 131 when the kettle is inclined. For example, the sealing weight 156 may be columnar or ball-shaped, and movement of the sealing weight 156 in the exhaust pipe 151 is relatively small. The sealing weight 156 may be a common material such as stainless steel, ceramic, or glass, which can reduce manufacturing costs. In addition, since the volume of the lid is limited, the mass of the sealing weight 156 can not be excessively large. If it is too large, the volume of the sealing weight 156 increases to a certain degree, and interference is likely to occur. The mass of the sealing weight 156 should not be too small, otherwise it affects the response speed of the rotation of the steam valve 15, which is disadvantageous to overflow prevention.

An elastic member 159 is provided between the end face of the closed end of the lower cover plate 12 and the exhaust pipe 151 in order to improve the hermeticity between the upper end of the exhaust pipe 151 and the periphery of the exhaust hole 131. [ And the elastic member 159 is installed so as to surround the rotating shaft 157 installed on the lower end surface of the exhaust pipe 151. [ This allows the elastic member 159 to quickly float up the exhaust pipe 151 to seal the upper end of the exhaust pipe 151 with the periphery of the exhaust hole 131 when the kettle 10 is inclined so that the steam valve 15 ) Overflow prevention effect. Here, the elastic member 159 may be a spring, a rubber pad, or a clip. Of course, the optimization of the elastic member 159 is a spring.

Referring to FIG. 6B, based on the above embodiment, it has been considered that, when the elastic member 159 is pressurized for a long time, the elastic function of the elastic member 159 may be reduced or become ineffective. In the present embodiment, the exhaust pipe 151 has a sleeve 158 extending from the end face of the closed end thereof, and the sleeve 158 is installed to surround the elastic member 159. In this way, even if the elastic member 159 undergoes an excessive pressure, the elastic member 159 undergoes permanent deformation under the supporting action of the sleeve 158.

The cross sectional area of the intake pipe 153 should be very small in consideration of the effect of the intake pipe 153 on the steam in the fourth aspect. Otherwise, when water in the kettle boils, 153 are relatively slow and can not smoothly flow toward the thermostat in the lower portion of the liquid heating vessel 10, which affects the response speed of the kettle 10 to cut off the power supply. In this case, since the kettle 10 is continuously heated for a predetermined period of time, the water in the kettle 10 boils and the pressure in the kettle becomes large, thus posing a risk of a safety accident. Since the space inside the lid is limited, the cross sectional area of the intake pipe can not be too large. Otherwise, when the intake pipe rotates, interference with other structures in the lid or with the inner lid of the lid is likely to occur. Which is disadvantageous to overflow prevention. Therefore, in this embodiment, the cross sectional area of the intake pipe 153 should be limited to some extent, and the cross sectional area thereof is S? [20 mm ² , 120 mm ² ].

3, 4A, 5A and 6A, among the above embodiments, the weight member 152 and the intake pipe 153 are formed such that the narrow angle range of the exhaust pipe 151 in the circumferential direction is relatively wide, 180 degrees. Here, if? Is too small, the water level in the liquid heating vessel 10 may be higher than the end of the intake pipe 153 when the liquid heating vessel 10 is inclined, Since the exhaust valve 151 can enter the exhaust pipe 151 from the end of the exhaust valve 153, the effect of preventing the overflow of the outlet valve 18 in the above embodiment is normal. In order to improve the overflow preventing effect of the outlet valve 18, the narrow angle between the expansion direction of the weight member 152 and the expansion direction of the intake pipe 153 is? ° ≤ α ≤ 180 °. Thus, even if the liquid heating vessel 10 is inclined, it is difficult for the distal end of the intake pipe 153 to be immersed in the liquid level in the liquid heating vessel 10, so that water is sucked from the intake pipe 153 into the exhaust pipe 151 The overflow prevention effect is enhanced.

The weight member 152 and the intake pipe 153 are provided on the opposite sides of the exhaust pipe 151 so as to face each other, Are disposed on both sides.

The water in the port body 10b immediately enters the lid 10a and further enters the exhaust pipe 151 through the intake pipe 153 as soon as the kettle 10 is tilted. If the rotation speed of the steam valve 15 is too slow, the exhaust pipe 153 can not wait until it is rotated to its maximum position, and the water immediately enters the exhaust pipe 153 (even if there is a relatively large difference And then the water in the lid 10 is flooded.

Referring to FIGS. 3 and 4A, in this embodiment, the intake pipe 153 may be a tube, may be an individual pipe, or may be a pipe body of other shapes. Obviously, the above-mentioned several types of pipe bodies have a relatively large area in contact with air in the rotating direction and a relatively large air resistance. In this embodiment, the intake pipe 153 is provided in a flat shape. This can prevent the water from flowing into the intake pipe 153 because the intake pipe 153 can rotate to the highest position at the highest speed when the kettle 10 is tilted.

In addition, in consideration of the fact that the radius of the lid 10a is usually 5 cm to 8 cm, the length of the intake pipe 153 must also be limited. If the intake pipe 153 is too long, the intake pipe 153 may easily interfere with other structures, and the entire steam valve 15 may not rotate. If the intake pipe 153 is too short, the end of the intake pipe 153 is submerged in water after the liquid heating vessel 10 is inclined. In this embodiment, the length of the intake pipe 153 is between 3 cm and 5 cm as a relatively good embodiment.

The intake pipe 153 and the exhaust pipe 151 may be integrally formed in consideration of the fact that the connection between the intake pipe 153 and the exhaust pipe 151 is tight. In this way, air and water do not leak because the sealing position of the connection position between the two is better.

Both the intake pipe 153 and the weight member 152 may be provided at arbitrary positions on the sidewall of the exhaust pipe 151. The intake pipe 153 and the weight member 152 may have a height difference in the vertical direction and both may be on the same rotation plane . As an optimization among the embodiments, both are located in the same rotation plane. Here, when the weight member 152 is located on a different rotation plane, the weight member 152 is disposed on the upper side and the intake pipe 153 is disposed downward. For example, when the weight member 152 rotates, In this process, the exhaust pipe 151 generates a resistance against the rotation of the weight member 152, the suction force of the intake pipe 153 is reduced, This is because the rotation is delayed to the best position. When both are located on the same rotation plane, the resistance of the exhaust pipe 151 is relatively small, so that the intake pipe 153 can be quickly rotated to the highest position.

The weight member 152 is installed on the side wall of the exhaust pipe 151 and the weight member 152 can be fixedly connected to the exhaust pipe 151. For example, . The weight member 152 may also be detachably connected to the exhaust pipe 151. The exhaust pipe 151 is a plastic member, the weight member 152 is a metal member, and the weight member 152 is fixed on the exhaust pipe 151 through secondary injection. Of the relatively good embodiments, the connection type of the weight member 152 and the exhaust pipe 151 is optimized for the detachable connection, for convenient installation, disconnection or replacement of the weight member 152. Specifically, the side wall of the exhaust pipe 151 has a protrusion 1512, and the weight member 152 is installed on the protrusion 1512. The side wall of the exhaust pipe 151 has a protrusion 1512 and has a protecting action against the exhaust pipe 151 through the connection between the protrusion 1512 and the weight member 152. If the weight member 152 is directly connected to the exhaust pipe 151 The installation of the weight member 152 may cause gas leakage or deformation of the exhaust pipe 151. [

3 and 4A, in another embodiment, the weight member 152 is fan-shaped and its centrifugal end is connected to the exhaust pipe 151. This is because, on the one hand, the fan-shaped weight member 152 is comparatively convenient to process and has a relatively low cost, and on the other hand, the fan-shaped weight member 152 has relatively small resistance at the time of rotation, Since the engine 153 can be quickly lifted.

Referring to FIGS. 2 and 8A, there are two situations when the kettle 10 is tilted. The first situation is that the kettle 10 is tilted by 90 °, and the second situation is that the kettle 10 is tilted by more than 90 ° like 180 °. When inclined by 90 DEG, the water is relatively difficult to permeate into the steam passage 14 in a relatively short time because the pressure is relatively small at the position around the exhaust pipe 151. However, when the kettle 10 is inclined by 180 DEG, the pressure is relatively large at the position around the exhaust pipe 151, so that the water seeps into the end face of the opening end of the exhaust pipe 151 in a relatively short time, Leakage may occur as it enters the passageway 14. In order to prevent the above situation, at least one blocking groove 1310 is formed in the end face of the closed end of the receiving groove 130, and at least one of the blocking holes 1310 is formed in the end face of the opening end of the exhaust pipe 151. [ There is a first blocking ring 154 that is inserted into the groove 1310 so that as the first blocking ring 154 is inserted into the blocking groove 1310 water flows into the steam passage 14 Can be effectively blocked. The overflow preventing effect of the steam valve 15 is improved.

Referring to FIG. 7, furthermore, when the kettle 10 is inclined, water may seep into the outer wall of the exhaust pipe 151 and enter the steam passage 14, and further leakage may occur.

In order to prevent water from penetrating into the outer wall of the exhaust pipe 151, a second blocking ring 155 extending toward the inner side wall of the receiving groove 130 is formed on the side of the exhaust pipe 151 have. Here, since the exhaust pipe 151 can rotate, no interference can occur between the exhaust pipe 151 and the inner wall of the receiving groove 130. Therefore, if a space is left between the exhaust pipe 151 and the receiving groove 130, since water can enter the steam passage 14 through the space, if the second blocking ring 155 is installed, The user may have a time margin to lift the kettle 10 because the blocking ring 155 can resist water and reduce the rate at which water enters the steam passage 14. [ Of course, two, three, or more than two third blocking rings 155 may be added to further reduce the rate at which water seeps into the steam passageway 14.

In the above embodiment, when the kettle 10 is tilted by 180 °, the positional pressure around the exhaust pipe 151 is comparatively large, so that water may leak into the steam passage 14 in a relatively short time, In another comparative embodiment, there is an encapsulant 156 in the exhaust pipe 151 to reduce the rate at which the water penetrates into the steam passage 14, or to prevent water from penetrating into the water flow passage The sealing weight 156 moves toward the open end of the exhaust pipe 151 from the closed end of the exhaust pipe 151 when the inclination angle of the exhaust pipe 151 is greater than 90 degrees, Thereby sealing the exhaust hole 131 of the stage.

Referring to Fig. 6A, it is considered that, based on the above embodiment, the sealing weight 156 can not block the exhaust pipe 151, and the exhaust of the exhaust pipe 151 is not smooth. Therefore, in the present embodiment, an air guide mechanism is provided on the inner wall of the exhaust pipe 151, and the air guide mechanism has an air guide passage formed between the sealing weight 156 and the inner wall of the exhaust pipe 151. Here, the air guide mechanism may be a protrusion such as a circular protrusion or a rib 1511 provided on the inner wall of the exhaust pipe 151, or may be a flow guide groove provided on the inner wall of the exhaust pipe. Here, the air guide mechanism is a plurality of ribs 1511 that optimally extend along the exhaust pipe axis direction and are distributed along the circumferential direction of the exhaust pipe, and the air guide passage is formed between adjacent ribs 1511.

Among the above embodiments, the sealing weight 156 may have various shapes, and it is only necessary to cover the exhaust hole 131 when the kettle is inclined. For example, the sealing weight 156 may be columnar or ball-shaped so that the movement resistance of the sealing weight 156 in the exhaust pipe 151 is relatively small, thereby making the movement more smooth.

In order to improve the hermeticity between the upper end of the exhaust pipe 151 and the periphery of the exhaust hole 131, an elastic member (not shown) is inserted between the lower cover plate 12 and the end face of the closed end of the exhaust pipe 151 The elastic member 159 is installed to surround the rotating shaft 157 installed on the lower end surface of the exhaust pipe 151. This allows the elastic member 159 to quickly float up the exhaust pipe 151 to seal the upper end of the exhaust pipe 151 with the periphery of the exhaust hole 131 when the kettle 10 is inclined so that the steam valve 15 ) Overflow prevention effect. Here, the elastic member 159 may be a spring, a rubber pad, or a clip. Of course, the optimization of the elastic member 159 is a spring.

Referring to FIG. 6A, it has been considered that, based on the above embodiment, when the elastic member 159 is subjected to a long period of pressure, the elastic function of the elastic member 159 may be reduced or become ineffective. In the present embodiment, the exhaust pipe 151 has a sleeve 158 extending from the end face of the closed end, and the sleeve 158 is installed to surround the elastic member 159. In this way, even if the elastic member 159 undergoes an excessive pressure, the elastic member 159 undergoes permanent deformation under the supporting action of the sleeve 158.

The above description is only an optimization example of the present invention, and therefore, the scope of the patent of the present invention is not limited thereby, and an equivalent structure conversion using the description of the present invention and the related contents under the idea of the present invention, Direct < / RTI > and / or indirect use in the domain are all within the scope of patent protection of the present invention.

10: liquid heating container 10a: lid
10 ': Cap body 10b: Port body
10c: power supply unit 11: upper cover plate
12: lower cover plate 13: bracket
14: Steam passage 15: Steam valve
16: Button 17: Lever
18: drain valve 19: sealing ring
100: second receiving groove 130: receiving groove
131: exhaust hole 141: spout
151: exhaust pipe 152: weight member
153: intake tube 154: first blocking ring
155: second blocking ring 156: sealing weight
157: rotating shaft 158: sleeve
159: elastic member 1510: exhaust port
1511: rib 1512: projection
1310: Blocking groove

Claims (30)

And an exhaust pipe having one end opened and the other end closed, wherein the exhaust pipe has a free rotation portion for allowing the exhaust pipe to rotate in its axial direction;
An intake pipe connected to the exhaust pipe and extending along a lateral direction of the exhaust pipe; And
A weight member connected to the exhaust pipe and extending along a lateral direction of the exhaust pipe;
Lt; / RTI >
Wherein the weight member and the intake pipe have a narrow angle alpha greater than 90 DEG and less than or equal to 180 DEG in the circumferential direction of the exhaust pipe and a gravity moment of rotation of the weight member about the free- Is greater than the rotating gravity moment,
Wherein the outer surface of the exhaust pipe has a watertight structure and the watertight structure includes at least one of a first blocking ring provided at least on an outer surface of the exhaust pipe and a second blocking ring provided on an end face of the exhaust pipe opening end, The plurality of blocking rings are arranged in order along the axial direction of the exhaust pipe, the second blocking rings are plural, and the plurality of blocking rings are distributed along the radial direction of the exhaust pipe
And a steam valve. The method according to claim 1,
Wherein the intake tube is provided in a flat shape, and the length of the intake tube is between 3 cm and 5 cm. The method according to claim 1,
Wherein the intake pipe and the exhaust pipe are integral and the intake pipe extends out along the radial direction of the exhaust pipe and is on the same rotation plane as the weight member. The method according to claim 1,
Wherein the weight member and the intake pipe have a narrow angle alpha of 170 DEG or more and less than or equal to 180 DEG in the circumferential direction of the exhaust pipe. The method according to claim 1,
Wherein a side wall of the exhaust pipe has a projection, and the weight member is detachably mounted on the projection. The method according to claim 1,
Wherein the exhaust pipe is a plastic member, the weight member is a metal member, and the weight member is fixed to the exhaust pipe through a secondary injection. The method according to claim 1,
Wherein the weight member is flat and its centrifugal end is connected to the exhaust pipe. The method according to claim 1,
Wherein the cross sectional area of the intake pipe is S? [20 mm ² , 120 mm ² ], the length of the intake pipe is L _0? [20 mm, 60 mm], the intake pipe is installed in a flat shape, And the area is installed in an elliptical shape. 9. The method of claim 8,
Wherein an abrasion resistant layer is provided on at least one of an opening end of the exhaust pipe and the free rotation portion. A cap body, an upper cover plate and a lower cover plate at both upper and lower ends of the cap body, and the steam valve according to any one of claims 1 to 9,
The cap body includes a steam passage having one end connected to the exhaust pipe opening end and the other end connected to the outside, and a rotation installing portion for installing the free rotation portion in the lid
Lt; / RTI > 11. The method of claim 10,
Wherein the cap body has an accommodating groove for accommodating the steam valve, one end of the accommodating groove is closed and the other end of the accommodating groove is in an open cylinder shape, the opening end face of the exhaust pipe touches the closed end face of the receiving groove, And a sealing end surface of the receiving groove has an exhaust hole connected to the exhaust pipe and the steam passage. 12. The method of claim 11,
Characterized in that there is at least one blocking groove in the end face of the receiving groove closed end and a first blocking ring inserted into the at least one blocking groove in the end face of the exhaust pipe opening end. 12. The method of claim 11,
And a side wall of the exhaust pipe has a second blocking ring extending toward at least one of the side walls of the receiving groove. 12. The method of claim 11,
And the sealing weight is moved toward the opening end of the exhaust pipe from the closed end of the exhaust pipe to seal the exhaust hole of the receiving groove closed end if the inclination angle of the exhaust pipe is greater than 90 degrees, Wherein the air guide mechanism has an air guide passage formed between the sealing weight and the inner wall of the exhaust pipe, and the air guide mechanism extends along the axial direction of the exhaust pipe and extends along the circumferential direction of the exhaust pipe Wherein the air guide passage is formed between the ribs adjacent to each other, and the sealing wept is provided in a columnar shape or a ball shape. 12. The method of claim 11,
Wherein the free rotation portion is a rotary shaft installed on an end surface of the exhaust pipe closed end, the rotary installation portion is a shaft hole provided in the lower cover plate, the rotation shaft is inserted into the shaft hole, Wherein the elastic member is provided so as to surround the rotating shaft, and the exhaust pipe has a sleeve extending from a closed end face thereof, and the sleeve And the elastic member is installed so as to surround the elastic member. 11. The method of claim 10,
Wherein the cap body further includes an outlet valve, a second receiving groove for receiving the outlet valve, and an outlet passage connecting the outlet valve and the outside, wherein the steam passage is connected to the outlet passage. 11. The method of claim 10,
Wherein the free rotation portion is a shaft hole provided in the exhaust pipe closed end, the rotation installing portion is a rotation shaft installed in the lower cover plate and into which the shaft hole is inserted,
Or the free rotation part is a bearing installed at the exhaust pipe opening end, and the rotation installing part is a bearing hole installed in the cap body to install the rotation shaft. 12. The method of claim 11,
The total volume of the watertight mechanism and the closed space formed between the inner wall of the receiving groove is V ₀ and the total volume between the exhaust pipe and the receiving groove inner wall is V ₁ and V ₀ / V ₁ ∈ [0.5, 0.95] Features a lid. 19. The method of claim 18,
Wherein at least one blocking groove is provided in the end face of the receiving groove sealing end, and the second blocking ring is inserted into the blocking groove. 20. The method of claim 19,
Wherein a length of the intake pipe is L ₀ , a radius of the lower cover plate is R, L _{0 /} R ∈ [0.6, 0.9], and a wear resistant layer is installed in the rotation mounting part. 11. The method of claim 10,
Wherein the weight member has a gravity moment rotating around the free rotation portion is greater than a sum of a gravity moment that the intake tube rotates around the free rotation portion and a frictional force moment between the cap body and the exhaust body when the exhaust pipe rotates Lid. 22. The method of claim 21,
Wherein the weight m ₁ of the weight member is greater than or equal to 10 g and less than or equal to 50 g and the mass m ₂ of the intake tract is greater than or equal to 5 g and less than or equal to 20 g. 22. The method of claim 21,
Wherein the weight of the weight member is G ₁ , the weight of the intake tract is G ₂ , and G ₁ / G ₂ ∈ [0.5, 12] or [1, 10]. 22. The method of claim 21,
Wherein an interval between the center of the weight member and the axis of the exhaust pipe is L ₁ , a distance between the center of the intake pipe and the axis of the exhaust pipe is L ₂ , L ₁ / L ₂ ∈ [2,20] , 15]. 22. The method of claim 21,
Wherein the cap body has an upper cover plate, a lower cover plate and a bracket, the bracket being between the upper cover plate and the lower cover plate and having a receiving groove for receiving the steam valve, Wherein an end of an opening end of the exhaust pipe is in contact with a closed end face of the receiving groove and an exhaust hole is formed in a closed end face of the receiving groove to connect the exhaust pipe and the steam passage, Wherein an elastic member is a spring, the inner diameter of the spring is D? [10 mm, 20 mm], the total number of turns is n? [4,12], and the stiffness coefficient , The mass m 3 ∈ [0.3 g, 1.5 g], and the exhaust pipe has a sleeve extending from its closed end face , Said sleeve cap, characterized in that, which is installed to surround the elastic member. 26. The method of claim 25,
Wherein said bracket also has an outlet valve, a second receiving groove for receiving said outlet valve, and an outlet passage connecting said outlet valve to the outside, said steam passage being connected to said outlet passage. Port body; And
Lid of paragraph 17
/ RTI >
The lid seals the port body and is hermetically connected to the inner wall of the port body
Lt; / RTI > 28. The method of claim 27,
Wherein a sealing ring is provided between the lower cover plate and the cap body and the cap is hermetically connected to the inner wall of the port body through the sealing ring. 28. The method of claim 27,
Wherein the lid and the port body are connected through a snap structure, wherein the snap structure includes a flexible latch mounted on the lid and a slot provided on the inner wall of the port body. delete

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