CN205214979U - Electric kettle - Google Patents

Abstract

The utility model discloses an electric kettle includes: the kettle body, the pot lid, the pot lid lid is on the hu kou of kettle body, outage response action module, the outage response action module set to the temperature of outage response module risees and breaks off when predetermineeing the outage temperature the galvanic circle that forms between electric kettle and the power, the steam flow executable module, steam flow carries out module setting and becomes to be used for to the flow direction outage response action module's steam volume is controlled in order can lengthen at least the outage response action module heat up extremely predetermine the outage required time of temperature. According to the utility model discloses electric kettle, the steam flow to flow direction outage response action module controls through the steam flow executable module, and the time point of resolving electric induction action module perception steam temperature that lags behind perhaps makes outage response action module intensify slowly, has lengthened electric kettle boiling back power -on time to the extension electric kettle boiling time, provide healthy and safe drinking water for the user.

Description

Insulating pot

Technical field

The utility model relates to an electro-technical field, particularly relates to a kind of insulating pot.

Background technology

Along with the raising of people's living standard, more and more higher to the requirement of drinking water, but in correlation technique, insulating pot heats up water temperature when usually reaching about 98 DEG C, the temperature controller of insulating pot will perform deenergization action, thus cause the water in insulating pot not seethed with excitement fully, the demand of people to healthy drinking water cannot be met.

Utility model content

The utility model is intended to solve one of technical problem in correlation technique at least to a certain extent.For this reason, the utility model proposes a kind of insulating pot, this insulating pot can extend the time of water boiling in kettle body.

Comprise according to insulating pot of the present utility model: kettle body; Pot lid, described pot lid covers on the Hu Kou of described kettle body; Power-off induction action module, disconnects the galvanic circle formed between described insulating pot and power supply when the temperature that described power-off induction action module is arranged in described power-off induction module is increased to default power-off temperature; Steam flow Executive Module, described steam flow Executive Module is arranged for and controls to be warming up to time needed for described default power-off temperature at least can extend described power-off induction action module to the quantity of steam flowing to described power-off induction action module.

According to insulating pot of the present utility model, by steam flow Executive Module, the steam flow flowing to power-off induction action module is controlled, delayed resolve electric induction action module perception vapor (steam) temperature time point or make power-off respond to action module to heat up slowly, extend insulating pot to seethe with excitement rear conduction time, thus extend insulating pot boiling time, for user provides healthy and safe drinking water.

According to insulating pot of the present utility model, also there is following additional technical feature:

According to an embodiment of the present utility model, described insulating pot has steam channel, and described steam channel is arranged at least part of steam Transportation in described kettle body to described power-off induction action module.

According to an embodiment of the present utility model, described steam flow Executive Module is at least partially disposed in described steam channel.

According to an embodiment of the present utility model, described steam flow Executive Module is arranged for the steam circulation area changing described steam channel.

According to an embodiment of the present utility model, described steam flow Executive Module is arranged to regulate described steam circulation area continuously.

According to an embodiment of the present utility model, described steam flow Executive Module comprises: temperature sensibility, described temperature sensibility to be arranged in described steam channel and described temperature sensibility be arranged to can perception vapor (steam) temperature deformation occurs to change the steam circulation area of described steam channel.

According to an embodiment of the present utility model, described temperature sensibility is configured to thermal sensitive piece, and described thermal sensitive piece is built in described steam channel.

According to an embodiment of the present utility model, described thermal sensitive piece comprises: body and the variant part that can deform, one end of described variant part is stiff end, and described stiff end is connected with described body, and the other end of described variant part is free end.

According to an embodiment of the present utility model, the relatively described steam channel of described thermal sensitive piece is detachable.

According to an embodiment of the present utility model, described steam flow Executive Module comprises: valve, and the relatively described steam channel position of described valve is adjustable, thus changes the steam circulation area of described steam channel.

According to an embodiment of the present utility model, described valve carries out position adjustments with the relatively described steam channel of rotating manner.

According to an embodiment of the present utility model, described valve at least has maximum open position and complete closed position, when described valve is in described maximum open position, described valve is configured to a part for the tube wall for the formation of described steam channel, when described valve is in described complete closed position, described valve cuts off described steam channel.

According to an embodiment of the present utility model, described valve can rotate between closed position in described maximum open position and completely relative to described steam channel.

According to an embodiment of the present utility model, described insulating pot also comprises: steam pipe, the described jet chimney of restriction place in described steam pipe, and described steam pipe comprises: the upper steam pipe, upper valve, lower valve and the lower steam pipe that are connected in turn.

According to an embodiment of the present utility model, described insulating pot also comprises: steam pipe, the described steam channel of restriction place in described steam pipe, and described steam pipe is built in the kettle body handle of described kettle body outer surface.

According to an embodiment of the present utility model, described steam flow Executive Module is hand steam flow Executive Module.

According to an embodiment of the present utility model, described steam pipe is arranged with seal and lower seal, described steam flow Executive Module is arranged between described upper seal and lower seal.

According to an embodiment of the present utility model, described upper seal is put between the outer surface and the inner surface of described handle of described steam pipe, and described lower seal is arranged between the outer surface of the outer surface of described steam pipe and the inner surface of described handle or described kettle body.

According to an embodiment of the present utility model, described upper seal and described lower seal are all configured to the flap seal cushion rubber of annular.

Accompanying drawing explanation

Fig. 1 is the structural representation of the insulating pot according to the utility model embodiment;

Fig. 2 is the exploded view of the steam pipe according to the utility model embodiment;

Fig. 3 is the top view of the thermal sensitive piece according to the utility model embodiment, and wherein, thermal sensitive piece is in complete closed position;

Fig. 4 is the front view of the thermal sensitive piece according to the utility model embodiment, and wherein, thermal sensitive piece is in full open position;

Fig. 5 is the partial sectional view of the insulating pot according to the utility model embodiment, and wherein, thermal sensitive piece is in complete closed position;

Fig. 6 is the partial sectional view of the insulating pot according to the utility model embodiment, and wherein, thermal sensitive piece is in full open position;

Fig. 7 is the exploded view of the steam pipe according to another embodiment of the utility model;

Fig. 8 is the partial sectional view of the insulating pot according to another embodiment of the utility model, and wherein, valve is in full open position;

Fig. 9 is the partial sectional view of the insulating pot according to another embodiment of the utility model, and wherein, valve is between full open position and completely between closed position;

Figure 10 is the partial sectional view of the insulating pot according to another embodiment of the utility model, and wherein, valve is in complete closed position;

Figure 11 is the partial enlarged drawing at A place in Figure 10;

Figure 12 is the structural representation of the insulating pot according to the utility model embodiment, and steam pipe is provided with seal and lower seal;

Figure 13 is the partial exploded view of the insulating pot according to the utility model embodiment.

Reference numeral:

Insulating pot 100;

Kettle body 10;

Power-off induction action module 200;

Steam flow Executive Module 300;

Steam channel 20;

Steam pipe 23; Upper steam pipe 231; Upper valve 232; Escape groove 2321; Lower valve 233; Lower steam pipe 234;

Temperature sensibility 30;

Thermal sensitive piece 31; Body 311; Body straightway 311a; Body segmental arc 311b; Variant part 312; Fillet 312a;

Handle 40;

Valve 50; Valve shaft 51;

Manual operation unit 60; Control stick 61;

Buffering air storing cavity 70;

Upper seal 81; Lower seal 82;

Pot lid 90.

Detailed description of the invention

Be described below in detail embodiment of the present utility model, the example of described embodiment is shown in the drawings.Be exemplary below by the embodiment be described with reference to the drawings, be intended to for explaining the utility model, and can not be interpreted as restriction of the present utility model.

Below with reference to Fig. 1 to Figure 13, the insulating pot 100 according to the utility model embodiment is described.As shown in Figure 1, this insulating pot 100 can comprise: kettle body 10, pot lid 90, power-off induction action module 200 and steam flow Executive Module 300, wherein, pot lid 90 covers on the Hu Kou of kettle body 10.

Particularly, the temperature that power-off induction action module 200 is arranged in power-off induction action module 200 disconnects the galvanic circle formed between insulating pot 100 and power supply when being increased to default power-off temperature.Power-off induction action module 200 can be located on kettle body 10, and the bottom surface of such as kettle body 10 can have pedestal, is provided with heating element heater in pedestal, and power-off induction action module 200 can be arranged in this pedestal.Steam channel 20 is for responding to action module 200 by least part of steam Transportation in kettle body 10 to power-off.Wherein, power-off induction action module 200 can the temperature of perception steam, and when the temperature of power-off induction action module 200 reaches setting value, power-off induction action module 200 can perform the action disconnecting insulating pot 100 power supply.That is, when the circuit of heating up water of insulating pot 100 is in conducting state, insulating pot 100 heats to the water in kettle body 10, after water boiling, steam can be transported to power-off induction action module 200 place, and the temperature of power-off induction action module 200 raises gradually, when the temperature of power-off induction action module 200 is elevated to setting value, power-off induction action module 200 can disconnect the circuit of heating up water of insulating pot 100, completes and heats up water.Wherein, power-off induction action module 200 can include temperature controller (scheming not shown), and temperature controller plays the effect of perception vapor (steam) temperature.

Steam flow Executive Module 300 is arranged for and controls to be warming up to time needed for default power-off temperature at least can extend power-off induction action module 200 to the steam flow flowing to described power-off induction action module 200.In other words, steam flow Executive Module 300 can control the steam flow flowing to power-off induction action module 200.Such as, steam flow Executive Module 300 can perform the action reducing to flow to power-off induction action module 200 steam, now, the steam flow flowing to power-off induction action module 200 in unit interval will reduce, and the time that power-off induction action module 200 is warming up to needed for default power-off temperature will extend.And for example, steam flow Executive Module 300 can perform the action increasing and flow to power-off induction action module 200 steam, now, the steam flow flowing to power-off induction action module 200 in unit interval will increase, and the time that power-off induction action module 200 is warming up to needed for default power-off temperature will shorten.For another example, steam flow Executive Module 300 can perform the completely isolated action flowing to power-off induction action module 200 steam, now, flowing to the steam flow of power-off induction action module 200 in unit interval, to level off to be zero, and the temperature of power-off induction action module 200 can not heat up, the circuit of heating up water of insulating pot 100 remains conducting, and the water in kettle body 10 is by constantly boiling.

According to the insulating pot 100 of the utility model embodiment, by steam flow Executive Module 300, the steam flow flowing to power-off induction action module 200 is controlled, delayed resolve electric induction action module 200 perception vapor (steam) temperature time point or make power-off respond to action module 200 to heat up slowly, extend the time that insulating pot 100 is energized, thus extend insulating pot 100 boiling time, for user provides healthy and safe drinking water.

In embodiments more of the present utility model, insulating pot 100 can have steam channel 20, and steam channel 20 is arranged at least part of steam Transportation in kettle body 10 to power-off induction action module 200.Can be transported to power-off induction action module 200 along steam channel 20 after water boiling in insulating pot 10, steam flow Executive Module 300 can by controlling the conducting state of steam channel 20 with the quantity of steam of control flow check to power-off induction action module 200.

In a specific embodiment of the present utility model, steam flow Executive Module 300 can be at least partially disposed in steam channel 20.In other words, steam flow Executive Module 300 can wholely be built in steam channel 20, as shown in Figure 5 and Figure 6.Steam flow Executive Module 300 also can a part in steam channel 20, remainder outside steam channel 20, as shown in Fig. 8 to Figure 10.

In a specific embodiment of the present utility model, insulating pot 100 also comprises steam pipe 23.Restriction place steam channel 20 in steam pipe 23.Steam pipe 23 can comprise: the upper steam pipe 231, upper valve 232, lower valve 233 and the lower steam pipe 234 that are connected in turn, as shown in Figure 2 and Figure 7.The upper end of upper valve 232 can be connected with upper steam pipe 231, and the lower end of upper valve 232 can be connected with lower steam pipe 234, and lower valve 233 is set in the periphery wall of the junction of valve 232 and lower steam pipe 234.Be understandable that, above-mentioned connected mode is only signal, is not to restriction of the present utility model.Welding, bonding, interference fit or clamping etc. can be adopted for upper steam pipe 231, upper valve 232, connected mode between lower valve 233 and lower steam pipe 234, not describe one by one here.

Steam pipe 23 can be built in kettle body 10 handle 40 of kettle body 10 outer surface.Thus, kettle body 10 internal structure can be simplified, be convenient to installation and the maintenance of insulating pot 100.But the utility model is not limited to this, steam pipe 23 also can be built in kettle body 10, here not at detailed description.

In specific embodiments more of the present utility model, steam flow Executive Module 300 is arranged for the steam circulation area changing steam channel 20.Be understandable that, when steam circulation area is larger, the quantity of steam flowing to power-off induction action module 200 in the unit interval is also comparatively large, and the temperature of power-off induction action module 200 is also very fast.When steam circulation area is less, the quantity of steam flowing to power-off induction action module 200 in the unit interval is also less, and the temperature of power-off induction action module 200 is also slower.Therefore, effectively can control the time of temperature to power-off preset temperature of power-off induction action module 200 by changing the steam circulation area of steam channel 20, thus delayed resolve electric induction action module 200 perception vapor (steam) temperature time point or make power-off respond to action module 200 to heat up slowly.

Steam flow Executive Module 300 can be hand steam flow Executive Module.That is, whether user can perform an action by Non-follow control steam flow Executive Module 300 as required, default power-off temperature-time is increased to when needing the temperature extending power-off induction operational module, then can perform the action of minimizing steam circulation area by Non-follow control steam flow Executive Module 300, when time expand reaches user's request, then can perform the action of stopping minimizing steam circulation area by Non-follow control steam flow Executive Module 300.If when user does not have the demand, then without the need to operating steam flow Executive Module 300.

In specific embodiments more of the present utility model, insulating pot 100 can also comprise: steam flow control module (scheming not shown).Steam flow control module is connected with steam flow Executive Module 300 and for controlling steam flow Executive Module 300 action.Such as, steam flow control module can be set with steam circulation size parameter, steam flow parameter, the time parameter that performs an action etc. thus control effectively to steam flow Executive Module 300.

Alternatively, steam flow Executive Module 300 can be arranged to regulate steam circulation area continuously.When steam circulation area is maximum, steam flow is maximum, and when steam circulation area is zero, steam flow is also zero.Steam flow Executive Module 300 can in steam circulation area, maximum and steam circulation area be regulate continuously between zero by steam circulation area, such as can be maximum to the minimum continuous adjustment of steam circulation area from steam circulation area.Or can be minimum to the maximum continuous adjustment of steam circulation area from steam circulation area.Be understandable that, need to reach the time point of delayed power-off induction action module 200 perception vapor (steam) temperature or make power-off respond to action module 200 when heating up slow, steam circulation area can be regulated from minimum to maximum variation tendency, thus the temperature that both can realize extending power-off induction action module 200 is to time needed for power-off temperature of presetting, the maintenance of insulating pot 100 is heated up water circuit.

In embodiments more of the present utility model, with reference to Fig. 5 and Fig. 6 composition graphs 3 and Fig. 4, steam flow Executive Module 300 can comprise: temperature sensibility 30, temperature sensibility 30 to be arranged in steam channel 20 and temperature sensibility 30 be arranged to can perception vapor (steam) temperature deformation occurs to change the steam circulation area of described steam channel 20.

Temperature sensibility 30 to be arranged in steam channel 20 and temperature sensibility 30 be arranged to can perception vapor (steam) temperature deformation occurs to change the steam circulation area of steam channel 20.In other words, owing to being provided with temperature sensibility 30 in steam channel 20, the steam produced after water boiling in kettle body 10 enters into the stop being subject to temperature sensibility 30 after in steam channel 20, steam directly can't be transported to power-off induction action module 200 (can certainly have fraction steam Transportation to power-off induction action module 200), after temperature sensibility 30 reaches predetermined temperature generation deformation, metamorphosis due to temperature sensibility 30 makes steam channel 20 conducting, a large amount of steam just can be transported to power-off induction action module 200, disconnect insulating pot 100 power supply when power-off induction action module 200 reaches preset temperature thus stop the boiling of water in kettle body 10.

Should be understood that, explanation is here schematic, can not be interpreted as it is that one to utility model limits.Steam channel 20 can cut off in original state by temperature sensibility 30 of the present utility model, and after deforming, steam channel 20 is in conducting state.Certainly, temperature sensibility 30 also can be partly cut off by steam channel 20 in original state, and the size of such as temperature sensibility 30 is little compared with the cross section of steam channel 20, and after deforming, the conducting degree of steam channel 20 increases.Namely, no matter how temperature sensibility 30 is arranged (such as can adopt two kinds of set-up modes presented here), as long as temperature sensibility 30 can change the steam circulation area of steam channel 20 after sense temperature deforms, just can change the quantity of steam flowing to power-off induction action module 200, such as reduce flow to power-off induction action module 200 quantity of steam or postpone steam to power-off induction action module 200 flow, such power-off induction action module 200 heats up slowly or power-off induction action module 200 delayed a period of time heats up, thus add the boiling time of water in kettle body 10, water is fully seethed with excitement.

In embodiments more of the present utility model, temperature sensibility 30 can be configured to thermal sensitive piece 31, and thermal sensitive piece 31 is built in steam channel 20.As shown in Figure 5 and Figure 6, thermal sensitive piece 31 is close to the internal face of steam channel 20 and steam channel 20 is isolated into the upper steam channel 20 being positioned at thermal sensitive piece 31 top and the lower steam channel 20 being positioned at thermal sensitive piece 31 bottom.The flowing that thermal sensitive piece 31 can overlap with steam circulating face to stop steam before deformation, thermal sensitive piece 31 reaches the downward deformation of preset temperature, upper and lower steam channel 20 is switched on, and power-off induction action module 200 is able to perception vapor (steam) temperature thus can controls the break-make of insulating pot 100 power supply.Thus, can steam pipe 231 and lower steam pipe 234 be come in conducting by the deformation of thermal sensitive piece 31 and then determine whether steam is transported to power-off induction action module 200.Here it should be noted that, the amplitude of thermal sensitive piece 31 deformation direction and deformation can be made adjustment as required.

In a specific embodiment of the present utility model, as shown in Figure 3 and Figure 4, thermal sensitive piece 31 can comprise: body 311 and the variant part 312 that deformation can occur, and one end of variant part 312 is stiff end, stiff end is connected with body 311, and the other end of variant part 312 is free end.The stiff end of variant part 312 is connected with body 311, and the free end of variant part 312 can swing up and down relative to body 311 place plane.Thus, the steam circulation area of steam channel 20 is changed.Such as, in an embodiment of the present utility model, variant part 312 is arranged in body 311 and a part of outer peripheral edge of variant part 312 and is connected with a part of inner peripheral of body 311.Body 311 and variant part 312 are in same plane substantially, another part outer peripheral edge of variant part 312 and another part inner peripheral of body 311 are fitted each other, and variant part 312 and the disjunct part of body 311 can depart from body 311 place plane thus realize changing the steam circulation area of steam channel 20.Thus, the time point that steam in steam channel 20 circulates and then plays delayed power-off induction action module 200 perception vapor (steam) temperature can be controlled.Certainly, body 311 can be horizontally set with in steam channel 20, variant part 312 can be that semicircle butterfly is lobate, two lobate outsides being symmetrically distributed in body 311 of semicircle butterfly, by changing the aperture of the lobate relative steam passage 20 of semicircle butterfly to change steam circulation area.Understandable, above-mentioned is only schematic, is not to restriction of the present utility model.

Alternatively, as shown in Figure 3 and Figure 4, body 311 can be configured to " D " shape and can comprise body straightway 311a and body segmental arc 311b, the two ends of body segmental arc 311b are connected with the two ends of body straightway 311a respectively thus form the annular body portion 311 closed, variant part 312 is arranged on the inner side of body 311 and suitable with the shape of body 311, variant part 312 has straight fillet 312a, and fillet 312a is connected with body straightway 311a.Thus, the manufacturing process of thermal sensitive piece 31 can be simplified, reduce the manufacturing cost of insulating pot 100.Wherein, the outer peripheral edge of body 311 can be fixed on the inwall of steam channel 20 by welding, bonding or the mode of riveting, and understandable, above-mentioned is only schematic, is not to restriction of the present utility model.

Certainly, thermal sensitive piece 31 also can removably connect by relative steam passage 20.Like this, if thermal sensitive piece 31 occurs that performance degradation accurately cannot control the break-make of steam channel 20, or when steam channel 20 has a foreign matters from being blocked, thermal sensitive piece 31 or dredging steam channel 20 can be changed in time to ensure that insulating pot 100 can normally work.

Steam pipe can be built in the handle 40 of the kettle body 10 of kettle body 10 outer surface.Thus, kettle body 10 internal structure can be simplified, simplify insulating pot 100 assembling procedure.Above-mentioned is only schematic, is not to restriction of the present utility model.

In some embodiments more of the present utility model, thermal sensitive piece 31 can be arranged between valve 232 and lower valve 233.Such as, thermal sensitive piece 31 can be fixed by a pin to valve 232 lower surface on and be built in steam channel 20 by the lower surface of upper valve 232 and the upper surface chucking power of lower steam pipe 234.Again such as, the inner peripheral surface of lower valve 233 can be formed with ledge structure, thermal sensitive piece 31 is arranged on the upper surface of ledge structure, and thermal sensitive piece 31 is close in the lower surface of upper valve 232.Therefore, under the fixation not having pin, also thermal sensitive piece 31 can be arranged at securely between upper valve 232 and lower valve 233, reduce parts usage.Wherein, the shape of thermal sensitive piece 31 is roughly consistent with the shape of ledge structure.

In some embodiments more of the present utility model, as shown in Fig. 7-Figure 11, steam flow Executive Module 300 can comprise valve 50.Valve 50 relative steam passage 20 position is adjustable, thus changes the steam circulation area of steam channel 20.Valve 50 relative steam passage 20 position is adjustable to change the steam circulation area of steam channel 20.In other words, the steam circulation area of steam channel 20 changes because of the change of valve 50 relative steam passage 20 position.Such as, valve 50 can all be positioned at outside steam channel 20, steam circulation area can reach maximum (now similar to the steam channel 20 of traditional electrical kettle 100), now, steam will be delivered to power-off induction action module 200 by normal discharge, and the temperature of power-off induction action module 200 reaches after setting value and will disconnect the power supply of insulating pot 100.And for example, a part for valve 50 can be positioned at steam channel 20, the part being positioned at steam channel 20 may be used for reducing steam circulation area, now, the flow that steam is transported to power-off induction action module 200 will reduce, the speed that power-off induction action module 200 heats up will slow down, and the boiling time of insulating pot 100 will extend.For another example, valve 50 also can all be placed in steam channel 20, and namely valve 50 overlaps with the cross section of steam channel 20, now, steam circulation area will level off to zero, and steam will be intercepted completely by valve 50 and substantially cannot be transported to power-off induction action module 200, and insulating pot 100 is by constantly boiling.Therefore, can realize by the relative position of control valve 50 relative steam passage 20 boiling time controlling insulating pot 100.Certainly, description is here only schematic, does not represent or imply that valve 50 of the present utility model is inevitable or necessarily have above-mentioned three positions.

In embodiments more of the present utility model, valve 50 at least has maximum open position (now, steam circulation area is maximum, as shown in Figure 8) and (now, steam circulation area is minimum in complete closed position, as shown in Figure 10), when valve 50 is in maximum open position, valve 50 is configured for a part for the tube wall forming steam channel 20, and when valve 50 is in complete closed position, valve 50 cuts off steam channel 20, now, valve 50 overlaps with the cross-sectional area of steam channel 20.Such design, when if desired extending the boiling time of insulating pot 100, can be arranged on complete closed position by valve 50; If desired stop boiling fast, then valve 50 can be arranged on maximum open position; Certainly, if desired proper extension insulating pot 100 boiling time, be unlikely to again the constantly boiling time too permanent, then valve 50 can be arranged between maximum open position and the position completely between closed position, namely suitably can reduce the position of the steam circulation area of steam channel 20.Thus, user can make different set-up modes as required, improves the practicality of insulating pot 100.

In addition, be not particularly limited according to the insulating pot 100 of the utility model embodiment mode for control valve 50 relative position, in embodiments more of the present utility model, valve 50 carries out position adjustments with rotating manner relative steam passage 20.Such as, valve 50 can be connected with the tube wall for the formation of steam channel 20 by valve shaft 51, and valve 50 relative steam passage 20 can rotate between closed position in maximum open position and completely.Wherein, valve shaft 51 can be arranged along the horizontal direction of the tube wall of steam channel 20, and valve shaft 51 also can be arranged (scheming not shown) along the longitudinal direction of the tube wall of steam channel 20.Certainly, the utility model is not limited to this, valve 50 also can carry out position adjustments by push-pull fashion relative steam passage 20, when inside steam channel 20, direction promotes, steam circulation area reduces, on the contrary, during toward the pull-out of steam channel 20 lateral direction, steam circulation area increases, and thus, realizes promoting amplitude size to change the steam circulation area of steam channel 20 by control valve 50.

Conveniently user regulates valve 50 position, the insulating pot 1001 of the utility model embodiment can also comprise manual operation unit 60, manual operation unit 60 is connected with the position of control valve 50 relative steam passage 20 with valve 50, it is outside that manual operation unit 60 can be emerging in kettle body 10 at least in part.In a specific embodiment of the present utility model, manual operation unit 60 can be configured to action bars 61, and a part for action bars 61 extends outward in kettle body 10 handle 40 kettle body 10.Like this, user can the position of hand-held operation bar 61 pairs of valves 50 regulate, and thus, can improve security and convenience that insulating pot 100 operates.

Alternatively, valve 50 is into a single integrated structure with control stick 61.Thus, valve 50 and action bars bonding strength can be improved, and be convenient to machine-shaping, reduce installation procedure.

In some embodiments more of the present utility model, as shown in Fig. 6 composition graphs 2, steam pipe 23 can be arranged with seal 81 and lower seal 82, thermal sensitive piece 31 is located between upper seal 81 and lower seal 82.That is, can limit in upper seal 81 and lower seal 82 and cushion air storing cavity 70.Be understandable that, no matter which kind of position thermal sensitive piece 31 is in relative to steam channel 20, all certain air gap can be there is in thermal sensitive piece 31 with the part that coordinates of upper valve 232, lower valve 233 and steam pipe 23, like this, after water boiling in insulating pot 100, steam can flow in the gap between handle 40 and steam pipe 21 from air gap.Buffering air storing cavity 70 can limit other positions of steam flow handle 40, gives the good experience sense of user.Steam is stored in buffering air storing cavity 70 and also can extends the time point of temperature controller perception vapor (steam) temperature or temperature controller is heated up slowly, thus extends the boiling time of insulating pot 100.

In some embodiments more of the present utility model, if Figure 12 is in conjunction with shown in Figure 13, steam pipe 21 can be arranged with seal 81 and lower seal 82, valve 50 is located between upper seal 81 and lower seal 82.That is, can limit in upper seal 81 and lower seal 82 and cushion air storing cavity 70.Be understandable that, no matter valve 50 is in complete closed position, or send out and be in maximum open position, or valve 50 is between complete closed position and maximum open position, all certain air gap can be there is in valve 50 with the part that coordinates of steam pipe 23, upper valve block door 232 and lower valve 233, like this, after the water boiling in insulating pot 100, steam can flow in the gap between handle 40 and steam pipe 23 from air gap.Buffering air storing cavity 70 can limit other positions of steam flow handle 40, thus other positions of handle 40 can not be hot because of steam, gives the better experience sense of user.Steam is stored in buffering air storing cavity 70 and also can extends the time point of temperature controller perception vapor (steam) temperature or temperature controller is heated up slowly, thus can prevent temperature controller from the boiling time of insulating pot 100 occurring early to jump or extend.

In a specific embodiment of the present utility model, upper seal 81 can be arranged between the outer surface of steam pipe 23 and the inner surface of handle 40, and lower seal 82 can be arranged between the outer surface of the outer surface of steam pipe 23 and the inner surface of handle 40 or kettle body 10.That is, the inner surface of upper seal 81, lower seal 82, kettle body handle 40 and the outer surface of steam pipe 23 can limit buffering air storing cavity 70 jointly, or upper seal 81, lower seal 82, the inner surface of kettle body handle 60 and the outer surface of kettle body can limit buffering air storing cavity 70 jointly.

In a specific embodiment of the present utility model, upper seal 81 and lower seal 82 all can be configured to the flap seal cushion rubber of annular.Such as, upper flap seal cushion rubber can be set between the outer surface of valve 232 and the inner surface of kettle body handle 40.Lower sheet sealing ring can be set between the outer surface of lower valve 233 and the inner surface of kettle body handle 40 or the outer surface of kettle body.Be understandable that, above-mentioned is only schematic, is not to restriction of the present utility model.

In the description of utility model, it will be appreciated that, term " on ", D score, " interior ", the orientation of the instruction such as " outward " or position relationship be based on orientation shown in the drawings or position relationship, only the utility model and simplified characterization for convenience of description, instead of the device of instruction or hint indication or element must have specific orientation, with specific azimuth configuration and operation, therefore can not be interpreted as restriction of the present utility model.

In the utility model, unless otherwise clearly defined and limited, the term such as term " installation ", " being connected ", " connection ", " fixing " should be interpreted broadly, and such as, can be fixedly connected with, also can be removably connect, or integral; It can be mechanical connection; Can be directly be connected, also indirectly can be connected by intermediary, can be the connection of two element internals or the interaction relationship of two elements, unless otherwise clear and definite restriction.For the ordinary skill in the art, the concrete meaning of above-mentioned term in the utility model can be understood as the case may be.

In the utility model, unless otherwise clearly defined and limited, fisrt feature second feature " on " or D score can be that the first and second features directly contact, or the first and second features are by intermediary mediate contact.

In the description of this description, specific features, structure, material or feature that the description of reference term " embodiment ", " some embodiments ", " example ", " concrete example " or " some examples " etc. means to describe in conjunction with this embodiment or example are contained at least one embodiment of the present utility model or example.In this manual, to the schematic representation of above-mentioned term not must for be identical embodiment or example.And the specific features of description, structure, material or feature can combine in one or more embodiment in office or example in an appropriate manner.In addition, when not conflicting, the feature of the different embodiment described in this description or example and different embodiment or example can carry out combining and combining by those skilled in the art.

Although illustrate and described embodiment of the present utility model above, be understandable that, above-described embodiment is exemplary, can not be interpreted as restriction of the present utility model, those of ordinary skill in the art can change above-described embodiment, revises, replace and modification in scope of the present utility model.

Claims (22)

1. an insulating pot, is characterized in that, comprising:

Kettle body;

Pot lid, described pot lid covers on the Hu Kou of described kettle body;

Power-off induction action module, disconnects the galvanic circle formed between described insulating pot and power supply when the temperature that described power-off induction action module is arranged in described power-off induction action module is increased to default power-off temperature;

Steam flow Executive Module, described steam flow Executive Module is arranged for and controls to be warming up to time needed for described default power-off temperature at least can extend described power-off induction action module to the steam flow flowing to described power-off induction action module.

2. insulating pot according to claim 1, is characterized in that, described insulating pot has steam channel, and described steam channel is arranged at least part of steam Transportation in described kettle body to described power-off induction action module.

3. insulating pot according to claim 2, is characterized in that, described steam flow Executive Module is at least partially disposed in described steam channel.

4. insulating pot according to claim 3, is characterized in that, described steam flow Executive Module is arranged for the steam circulation area changing described steam channel.

5. insulating pot according to claim 4, is characterized in that, described steam flow Executive Module is arranged to regulate described steam circulation area continuously.

6. insulating pot according to claim 2, it is characterized in that, described steam flow Executive Module comprises: temperature sensibility, described temperature sensibility to be arranged in described steam channel and described temperature sensibility be arranged to can perception vapor (steam) temperature deformation occurs to change the steam circulation area of described steam channel.

7. insulating pot according to claim 6, is characterized in that, described temperature sensibility is configured to thermal sensitive piece, and described thermal sensitive piece is built in described steam channel.

8. insulating pot according to claim 7, it is characterized in that, described thermal sensitive piece comprises: body and the variant part that deformation can occur, and one end of described variant part is stiff end, described stiff end is connected with described body, and the other end of described variant part is free end.

9. insulating pot according to claim 7, is characterized in that, the relatively described steam channel of described thermal sensitive piece is detachable.

10. insulating pot according to claim 7, it is characterized in that, the internal face of described thermal sensitive piece and described steam channel is close to and described steam channel is isolated into the upper steam channel being positioned at thermal sensitive piece top and the lower steam channel being positioned at described thermal sensitive piece bottom.

11. insulating pots according to claim 2, is characterized in that, described steam flow Executive Module comprises: valve, and the relatively described steam channel position of described valve is adjustable, thus change the steam circulation area of described steam channel.

12. insulating pots according to claim 11, is characterized in that, described valve carries out position adjustments with the relatively described steam channel of rotating manner.

13. insulating pots according to claim 11, it is characterized in that, described valve at least has maximum open position and complete closed position, when described valve is in described maximum open position, described valve is configured to a part for the tube wall for the formation of described steam channel, when described valve is in described complete closed position, described valve cuts off described steam channel.

14. insulating pots according to claim 13, is characterized in that, described valve can rotate between closed position in described maximum open position and completely relative to described steam channel.

15. insulating pots according to claim 2, is characterized in that, also comprise:

Steam pipe, limits described steam channel in described steam pipe, and described steam pipe comprises: the upper steam pipe, upper valve, lower valve and the lower steam pipe that are connected in turn.

16. insulating pots according to claim 2, is characterized in that, also comprise:

Steam pipe, limits described steam channel in described steam pipe, and described steam pipe is built in the kettle body handle of described kettle body outer surface.

17. insulating pots according to claim 1, is characterized in that, described steam flow Executive Module is hand steam flow Executive Module.

18. insulating pots according to claim 1, is characterized in that, also comprise: steam flow control module, and described steam flow control module is connected with described steam flow Executive Module and for controlling the action of described steam flow Executive Module.

19. insulating pots according to claim 1, is characterized in that, described power-off induction action module comprises temperature controller.

20. insulating pots according to claim 16, is characterized in that, described steam pipe are arranged with seal and lower seal, and described steam flow Executive Module is arranged between described upper seal and lower seal.

21. insulating pots according to claim 20, it is characterized in that, described upper seal is arranged between the outer surface of described steam pipe and the inner surface of described handle, and described lower seal is arranged between the outer surface of the outer surface of described steam pipe and the inner surface of described handle or described kettle body.

22. insulating pots according to claim 21, is characterized in that, described upper seal and described lower seal are all configured to the flap seal cushion rubber of annular.