CN205102407U - A electric water heater that is used for electric water heater's guiding subassembly and has it - Google Patents

Abstract

The utility model discloses an electric water heater that is used for electric water heater's guiding subassembly and has it. A guiding subassembly includes the guide plate and the dampening capsule of intaking for electric water heater, be equipped with on the guide plate and communicate respectively the upper portion space of guide plate and the dampening capsule pilot hole in lower part space and play water water conservancy diversion passageway, the dampening capsule of intaking installs in the dampening capsule pilot hole, intake be equipped with on the dampening capsule with the cover body water inlet of upper portion space intercommunication and with the cover body delivery port of lower part space intercommunication. According to the utility model discloses a hot water outlet rate that is used for electric water heater's guiding subassembly, can improve electric water heater.

Description

For electric heater guiding subassembly and there is its electric heater

Technical field

The utility model relates to electrical equipment manufacturing technology field, especially relates to a kind of guiding subassembly for electric heater and has the described electric heater for the guiding subassembly of electric heater.

Background technology

In correlation technique, the hot water delivery rate of electric heater is low, causes the energy saving of electric heater poor.

Utility model content

The utility model is intended at least to solve one of technical problem existed in prior art.For this reason, the utility model needs to provide a kind of guiding subassembly for electric heater, and the described guiding subassembly for electric heater can improve the hot water delivery rate of electric heater.

The utility model also needs to provide a kind of electric heater.

According to the guiding subassembly for electric heater of the utility model first aspect embodiment, comprising: deflector, described deflector is provided with impact-absorbing shell pilot hole and the water outlet flow-guiding channel of upper space and the lower space being communicated with described deflector respectively; Water inlet impact-absorbing shell, described water inlet impact-absorbing shell is arranged in described impact-absorbing shell pilot hole, and described water inlet impact-absorbing shell is provided with the cover body water inlet be communicated with described upper space and the cover body delivery port be communicated with described lower space.

According to the guiding subassembly for electric heater of the utility model embodiment, utilize water inlet impact-absorbing shell and water outlet flow-guiding channel to the buffer deceleration of current entering electric heater, reduce the mixability of cold water and hot water, thus improve the hot water delivery rate of electric heater.

According to embodiments more of the present utility model, described deflector is provided with outlet pipe locating hole and the magnesium rod locating hole of through described deflector respectively.

According to embodiments more of the present utility model, described deflector comprises: plate body, and described impact-absorbing shell pilot hole is located on described plate body; Edge, some sides, some described sides are along being connected with the edge of described plate body respectively and extending to described lower space, and described water outlet flow-guiding channel is located at described plate body and/or described side along upper.

Alternatively, described water outlet flow-guiding channel comprises: water outlet relief hole, and described water outlet relief hole is located on described plate body; And/or water outlet guiding gutter, described water outlet guiding gutter is located at described side along upper.

Alternatively, described side is along being of a size of 5-15 millimeter in the vertical direction.

According to an embodiment of the present utility model, the upper surface of described water inlet impact-absorbing shell is higher than the upper surface of described deflector.

According to embodiments more of the present utility model, described water inlet impact-absorbing shell comprises: cover body, described cover body is arranged in described impact-absorbing shell pilot hole, on the upper surface that described cover body water inlet is located at described cover body and the lower surface of described cover body open wide to form described cover body delivery port; Labyrinth structure, described labyrinth structure is located in described cover body, and the lower surface of described labyrinth structure is lower than the lower surface or concordant with the lower surface of described cover body of described cover body.

In embodiments more of the present utility model, described labyrinth structure comprises multiple arc, on the inner roof wall face that multiple described arc is connected to described cover body and be distributed in described cover body water inlet concentric arrange circumferentially multiple, arc circumferentially described in each along the circumferential interval of described cover body water inlet arrange and adjacent described in arc circumferentially to stagger in the circumference of described cover body water inlet setting.

In other embodiments of the present utility model, described labyrinth structure comprises: multiple arc, on the inner roof wall face that multiple described arc is connected to described cover body and be distributed in described cover body water inlet concentric arrange circumferentially multiple, arc circumferentially described in each along the circumferential interval of described cover body water inlet arrange and adjacent described in arc circumferentially to stagger in the circumference of described cover body water inlet setting, the lower surface of described arc is lower than the lower surface of described cover body; Screens, described screens to be located at below described cover body and around multiple described arc.

Preferably, described screens is made up of some layers of stainless (steel) wire, and the aperture of every layer of described stainless (steel) wire is 50-300 order.

In other embodiment of the present utility model, described labyrinth structure comprises: multiple arc, on the inner roof wall face that multiple described arc is connected to described cover body and be distributed in described cover body water inlet concentric arrange circumferentially multiple, arc circumferentially described in each along the circumferential interval of described cover body water inlet arrange and adjacent described in arc circumferentially to stagger in the circumference of described cover body water inlet setting, the lower surface of described arc is lower than the lower surface of described cover body; Sleeve, described sleeve to be located at below described cover body and around multiple described arc, and the lower surface of described sleeve is higher than the lower surface or concordant with the lower surface of described arc of described arc.

According to the electric heater of the utility model second aspect embodiment, comprising: inner bag, described inner bag is provided with water inlet pipe and outlet pipe; Guiding subassembly, described guiding subassembly is the guiding subassembly for electric heater according to the above-mentioned first aspect embodiment of the utility model, described guiding subassembly is located in described inner bag, one end of described water inlet pipe is stretched into described upper space and is communicated with the cover body water inlet of described water inlet impact-absorbing shell, and described upper space is stretched in one end of described outlet pipe.

According to the electric heater of the utility model embodiment, utilize as above for the guiding subassembly of electric heater, hot water delivery rate is high, good energy saving property.

Additional aspect of the present utility model and advantage will part provide in the following description, and part will become obvious from the following description, or be recognized by practice of the present utility model.

Accompanying drawing explanation

Fig. 1 is the stereogram of the guiding subassembly for electric heater according to the utility model embodiment;

Fig. 2 is the enlarged diagram in the A portion that Fig. 1 centre circle shows;

Fig. 3 is the side view of the guiding subassembly for electric heater according to the utility model embodiment;

Fig. 4 is the upward view of the guiding subassembly for electric heater according to the utility model embodiment;

Fig. 5 is the stereogram of the guiding subassembly for electric heater according to other embodiments of the utility model;

Fig. 6 is the enlarged diagram in the B portion that Fig. 5 centre circle shows;

Fig. 7 is the side view of the guiding subassembly for electric heater according to other embodiments of the utility model;

Fig. 8 is the upward view of the guiding subassembly for electric heater according to other embodiments of the utility model;

Fig. 9 is the stereogram of the guiding subassembly for electric heater according to the other embodiment of the utility model;

Figure 10 is the enlarged diagram in the C portion that Fig. 9 centre circle shows;

Figure 11 is the side view of the guiding subassembly for electric heater according to the other embodiment of the utility model;

Figure 12 is the upward view of the guiding subassembly for electric heater according to the other embodiment of the utility model;

Figure 13 is the structural representation of the electric heater according to the utility model embodiment.

Reference numeral:

For the guiding subassembly 100 of electric heater,

Deflector 1, upper space 11, lower space 12, impact-absorbing shell pilot hole 13, water outlet flow-guiding channel 14, water outlet relief hole 141, water outlet guiding gutter 142, outlet pipe locating hole 15, magnesium rod locating hole 16, plate body 17, side along 18,

Water inlet impact-absorbing shell 2, cover body water inlet 21, cover body delivery port 22, cover body 23, labyrinth structure 24, arc 241, screens 242, sleeve 243,

Electric heater 200,

Inner bag 3, water inlet pipe 4, outlet pipe 5.

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, and wherein same or similar label represents same or similar element or has element that is identical or similar functions from start to finish.Being exemplary below by the embodiment be described with reference to the drawings, only for explaining the utility model, and can not being interpreted as restriction of the present utility model.

Describe the guiding subassembly 100 for electric heater according to the utility model first aspect embodiment below with reference to Fig. 1-Figure 13, described guiding subassembly 100 is applicable to electric heater, can improve the hot water delivery rate of electric heater.Wherein, electric heater can be storage-type electric water heater.

As shown in Fig. 1-Figure 13, according to the guiding subassembly 100 for electric heater of the utility model embodiment, comprise deflector 1 and water inlet impact-absorbing shell 2.

Specifically, the space of inner container of electric water heater is divided into upper space 11 and lower space 12 by deflector 1, upper space 11 is positioned at the top of deflector 1 and lower space 12 is positioned at the below of deflector 1, and the cold water of lower space 12 pours in upper space 11 and is heated to be hot water.Deflector 1 is provided with the impact-absorbing shell pilot hole 13 and water outlet flow-guiding channel 14 that are communicated with upper space 11 and lower space 12 respectively, water inlet impact-absorbing shell 2 is arranged in impact-absorbing shell pilot hole 13, and water inlet impact-absorbing shell 2 is provided with the cover body water inlet 21 be communicated with upper space 11 and the cover body delivery port 22 be communicated with lower space 12.

Like this, during electric water heater inlet, cold water enters in water impact-absorbing shell 2 by cover body water inlet 21, lower space 12 is flowed into afterwards from cover body delivery port 22, upper space 11 is poured in finally by water outlet flow-guiding channel 14, thus slow down the water intake velocity of electric heater, the cold water reducing lower space 12 is to the disturbance of the hot water of upper space 11, and the hot water making the cold water of lower space 12 slowly can promote upper space 11 flows out electric heater.

According to the guiding subassembly 100 for electric heater of the utility model embodiment, utilize water inlet impact-absorbing shell 2 and water outlet flow-guiding channel 14 to the buffer deceleration of current entering electric heater, reduce the mixability of cold water and hot water, thus improve the hot water delivery rate of electric heater.

According to embodiments more of the present utility model, deflector 1 is provided with outlet pipe locating hole 15 and the magnesium rod locating hole 16 of through deflector 1 respectively, such outlet pipe and magnesium rod can be fixed on deflector 1, avoid rocking of outlet pipe and magnesium rod, thus be conducive to the mixability reducing cold water and hot water.Such as, as shown in drawings, outlet pipe locating hole 15 and magnesium rod locating hole 16 can be located at the right side of impact-absorbing shell pilot hole 13 successively, thus facilitate the installation of outlet pipe and magnesium rod.

As shown in Fig. 1-Figure 12, according to embodiments more of the present utility model, deflector 1 can comprise plate body 17 and some sides along 18.Wherein, impact-absorbing shell pilot hole 13 is located on plate body 17, and some sides to be connected with the edge of plate body 17 and lower portion space 12 extends respectively along 18, and water outlet flow-guiding channel 14 is located at plate body 17 and/or side along on 18.Such as, as shown in drawings, plate body 17 is formed as general rectangular, four sides are connected with the edge of plate body 17 surrounding respectively along 18, each side along 18 by the edge of plate body 17 to downward-extension, two sides on fore-and-aft direction extend in left-right direction along 18, two sides on left and right directions extend substantially along the longitudinal direction along 18, water outlet flow-guiding channel 14 is located at two sides on plate body 17 and above-mentioned left and right directions along on 18, springing up of water inlet current can be cushioned like this in lower space 12, and current not only can from bottom to top pour in upper space 11 by the water outlet flow-guiding channel 14 on plate body 17, upper space 11 can also be poured in along the water outlet flow-guiding channel 14 on 18 from the left and right sides of deflector 1 by the side of two on above-mentioned left and right directions.Certainly, water outlet flow-guiding channel 14 only can also be located on plate body 17 or only be located at side along on 18.

Alternatively, water outlet flow-guiding channel 14 can comprise water outlet relief hole 141 and/or water outlet guiding gutter 142, and wherein water outlet relief hole 141 is located on plate body 17, and water outlet guiding gutter 142 is located at side along on 18.Such as, as shown in Fig. 1, Fig. 4-Fig. 5, Fig. 8-Fig. 9 and Figure 12, water outlet relief hole 141 is circular hole, water outlet guiding gutter 142 runs through the lower surface of side along 18 and cross-sectional profiles is rectangle substantially, wherein water outlet relief hole 141 and water outlet guiding gutter 142 are multiple, and the cold water entering lower space 12 so upwards, by water outlet guiding gutter 142 can upwards pour in upper space 11 from the left and right sides of deflector 1 respectively by water outlet relief hole 141.Be understandable that, water outlet flow-guiding channel 14 just can also be located at the water outlet relief hole 141 on plate body 17 or just be located at side along the water outlet guiding gutter 142 on 18.

Here, the shape of water outlet relief hole 141 and water outlet guiding gutter 142 is not limited thereto, and such as, water outlet relief hole 141 can also be the hole of elliptical aperture, polygonal hole or other shapes.And for example, the cross-sectional profiles of water outlet guiding gutter 142 can also be trapezoidal or semicircle.Similarly, the utility model does not do particular determination for the arrangement mode of water outlet relief hole 141, as long as ensure that the gross area of water outlet relief hole 141 is greater than the water inlet area of cold water, such as, as in accompanying drawing, multiple water outlet relief hole 141 is distributed in on the multiple concentric circles that are the center of circle of the center of impact-absorbing shell pilot hole 13.Certainly, multiple water outlet relief hole 141 can also be distributed in on the multiple concentric circles that are the center of circle of the center of outlet pipe locating hole 15 or magnesium rod locating hole 16.It will also be appreciated that, as shown in drawings, multiple water outlet relief holes 141 on each concentric circles can be uniformly distributed, and the arrangement density of the water outlet relief hole 141 of close impact-absorbing shell pilot hole 13 is greater than the arrangement density of the water outlet relief hole 141 away from impact-absorbing shell pilot hole 13 place, multiple water outlet guiding gutter 142 is evenly distributed on side along on 18.

Alternatively, side can be 5-15 millimeter along 18 sizes in the vertical direction.

In some embodiments such as shown in Fig. 1-Fig. 3, Fig. 5-Fig. 7 and Fig. 9-Figure 11, the upper surface of water inlet impact-absorbing shell 2, higher than the upper surface of deflector 1, can effectively prevent cold water to be spilled over to upper space 11 from the impact-absorbing shell pilot hole 13 of deflector 1 like this.

As shown in Fig. 1-Figure 12, according to embodiments more of the present utility model, water inlet impact-absorbing shell 2 can comprise cover body 23 and labyrinth structure 24.Cover body 23 is arranged in impact-absorbing shell pilot hole 13, on the upper surface that cover body water inlet 21 is located at cover body 23 and the lower surface of cover body 23 open wide to form cover body delivery port 22, such cold water flows through deflector 1 from top to bottom and enters lower space 12.Labyrinth structure 24 is located in cover body 23, the lower surface of labyrinth structure 24 is lower than the lower surface or concordant with the lower surface of cover body 23 of cover body 23, namely the lower surface of labyrinth structure 24 is positioned at the below of the lower surface of cover body 23, or the lower surface of the lower surface of labyrinth structure 24 and cover body 23 is located in the same horizontal plane, thus it is not only easy to assembly, and the cold water making to enter in cover body 23 is after the deceleration of labyrinth structure 24, can be forced down on the diapire of inner container of electric water heater by labyrinth structure 24, the mixability of such cold water and hot water is reduced further.Preferably, water inlet impact-absorbing shell 2 is formed in one part, which simplify the structure of guiding subassembly 100, and water inlet impact-absorbing shell 2 is easy to assembly.

As Figure 1-Figure 4, in embodiments more of the present utility model, labyrinth structure 24 can comprise multiple arc 241, on the inner roof wall face that multiple arc 241 is connected to cover body 23 and be distributed in cover body water inlet 21 concentric arrange circumferentially multiple, each arc 241 circumferentially arranges the setting and arc 241 in adjacent circumferential staggers in the circumference of cover body water inlet 21 along the circumferential interval of cover body water inlet 21.

Particularly, as in accompanying drawing, multiple arc 241 is connected on the upper wall surface in cover body 23, multiple arc 241 to be distributed in cover body water inlet 21 concentric two of arranging circumferentially, each arc 241 is circumferentially arranged along the circumferential uniform intervals of cover body water inlet 21, be positioned at the cross-sectional profiles of the arc 241 circumferentially of inner side for substantially "T"-shaped, the cross-sectional profiles being positioned at the arc 241 circumferentially in outside is circular arc, "T"-shaped arc 241 staggers with circular arc arc 241 and arranges in the circumference of cover body water inlet 21, thus, the cold water entered in cover body 23 flows downward from inside to outside, and be lowered gradually at flowing velocity and pressure after "T"-shaped arc 241 and circular arc arc 241, thus slow down springing up of cold water, reduce the disturbance of cold water to hot water.

As shown in Figure 5-Figure 8, in other embodiments of the present utility model, labyrinth structure 24 can comprise multiple arc 241 and screens 242, on the inner roof wall face that multiple arc 241 is connected to cover body 23 and be distributed in cover body water inlet 21 concentric arrange circumferentially multiple, each arc 241 circumferentially arranges the setting and arc 241 in adjacent circumferential staggers in the circumference of cover body water inlet 21 along the circumferential interval of cover body water inlet 21, the lower surface of arc 241 is lower than the lower surface of cover body 23, screens 242 to be located at below cover body 23 and around multiple arc 241.

Particularly, as in accompanying drawing, multiple arc 241 is connected on the upper wall surface in cover body 23, multiple arc 241 to be distributed in cover body water inlet 21 concentric two of arranging circumferentially, each arc 241 is circumferentially arranged along the circumferential uniform intervals of cover body water inlet 21, be positioned at the cross-sectional profiles of the arc 241 circumferentially of inner side for substantially "T"-shaped, the cross-sectional profiles being positioned at the arc 241 circumferentially in outside is circular arc, "T"-shaped arc 241 staggers with circular arc arc 241 and arranges in the circumference of cover body water inlet 21, thus, the cold water entered in cover body 23 flows downward from inside to outside, and be lowered gradually at flowing velocity and pressure after "T"-shaped arc 241 and circular arc arc 241, thus slow down springing up of cold water, reduce the disturbance of cold water to hot water, and, lower surface due to arc 241 is positioned at the below of the lower surface of cover body 23, cold water can be forced down on the diapire of electric heater by arc 241.

As shown in Fig. 5-Fig. 6 and Fig. 8, screens 242 is around multiple circular arc arc 241 and be positioned at the outside of multiple circular arc arc 241, thus the flowing velocity of cold water can be slowed down further, and, because screens 242 is spaced apart with the water inlet pipe stretching into cover body water inlet 21, screens 242 has gap with the diapire of electric heater, thus effectively can avoid the blocking of water inlet pipe.As preferably, screens 242 can be made up of some layers of stainless (steel) wire, and the aperture of every layer of stainless (steel) wire is 50-300 order, thus screens 242 can slow down water intake velocity more effectively.Here, " some " can refer to one, also can refer to multiple.

As shown in Fig. 9-Figure 12, in other embodiment of the present utility model, labyrinth structure 24 can also comprise multiple arc 241 and sleeve 243, on the inner roof wall face that multiple arc 241 is connected to cover body 23 and be distributed in cover body water inlet 21 concentric arrange circumferentially multiple, each arc 241 circumferentially arranges the setting and arc 241 in adjacent circumferential staggers in the circumference of cover body water inlet 21 along the circumferential interval of cover body water inlet 21, the lower surface of arc 241 is lower than the lower surface of cover body 23, sleeve 243 to be located at below cover body 23 and around multiple arc 241, the lower surface of sleeve 243 is higher than the lower surface or concordant with the lower surface of arc 241 of arc 241.

Particularly, as in accompanying drawing, multiple arc 241 is connected on the upper wall surface in cover body 23, multiple arc 241 to be distributed in cover body water inlet 21 concentric two of arranging circumferentially, each arc 241 is circumferentially arranged along the circumferential uniform intervals of cover body water inlet 21, be positioned at the cross-sectional profiles of the arc 241 circumferentially of inner side for substantially "T"-shaped, the cross-sectional profiles being positioned at the arc 241 circumferentially in outside is circular arc, "T"-shaped arc 241 staggers with circular arc arc 241 and arranges in the circumference of cover body water inlet 21, thus, the cold water entered in cover body 23 flows downward from inside to outside, and be lowered gradually at flowing velocity and pressure after "T"-shaped arc 241 and circular arc arc 241, thus slow down springing up of cold water, reduce the disturbance of cold water to hot water, and, lower surface due to arc 241 is positioned at the below of the lower surface of cover body 23, cold water can be forced down on the diapire of electric heater by arc 241.

As shown in Fig. 9-Figure 10 and Figure 12, sleeve 243 is around multiple circular arc arc 241 and be positioned at the outside of multiple circular arc arc 241, the lower surface of sleeve 243 and the lower surface of arc 241 are located in the same horizontal plane, thus the flowing velocity of cold water can be slowed down further, and the bottom interval certain distance of sleeve 243 and electric heater, effectively can reduce the water layer height of the cold water entering electric heater, thus further reduce cold water to the disturbance of hot water.

As shown in Fig. 1-Figure 13, according to the electric heater 200 of the utility model second aspect embodiment, comprise inner bag 3 and guiding subassembly.

Wherein, inner bag 3 is provided with water inlet pipe 4 and outlet pipe 5, guiding subassembly is the guiding subassembly 100 for electric heater according to the utility model above-described embodiment, guiding subassembly 100 is located in inner bag 3, the right-hand member of water inlet pipe 4 stretches into upper space 11 and is communicated with the cover body water inlet 21 of water inlet impact-absorbing shell 2, and upper space 11 is stretched in the upper end of outlet pipe 5.Preferably, water inlet pipe 4 stretches into in water impact-absorbing shell 2, and guiding subassembly 100 is located at the bottom of inner bag 3, thus cold water can be avoided to flow out on the upside of deflector 1, and cold water can force down on the diapire of inner bag 3 by labyrinth structure 24, thus reduce the mixability of the hot water of cold water and upper space 11.

When electric heater 200 is intake, cold water enters into water impact-absorbing shell 2 by water inlet pipe 4, after the buffering of labyrinth structure 24, the flowing velocity of cold water and flowing pressure decline and enter lower space 12, the cold water of lower space 12 pours in upper space 11 by water outlet flow-guiding channel 14 more afterwards, the hot water promoting upper space 11 enters outlet pipe 5, last hot water flows out electric heater 200 from outlet pipe 5, thus the disturbance of cold water to hot water is little, reduces the impact of cold water on the leaving water temperature of hot water.

According to the electric heater 200 of the utility model embodiment, utilize as above for the guiding subassembly 100 of electric heater, hot water delivery rate is high, good energy saving property.

In description of the present utility model, it will be appreciated that, term " " center ", " on ", D score, " front ", " afterwards ", " left side ", " right side ", " level ", " top ", " end ", " interior ", " outward ", orientation or the position relationship of the instruction such as " circumference " are based on orientation shown in the drawings or position relationship, only the utility model and simplified characterization for convenience of description, instead of indicate or imply that the device of 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 description of the present utility model, except as otherwise noted, the implication of " multiple " is two or more.

In description of the present utility model, it should be noted that, unless otherwise clearly defined and limited, term " installation ", " being connected ", " connection " should be interpreted broadly, and such as, can be fixedly connected with, also can be removably connect, or connect integratedly; Can be mechanical connection, also can be electrical connection; Can be directly be connected, also indirectly can be connected by intermediary, can be the connection of two element internals.For the ordinary skill in the art, concrete condition the concrete meaning of above-mentioned term in the utility model can be understood.

In the description of this description, specific features, structure, material or feature that the description of reference term " embodiment ", " some embodiments " etc. means to describe in conjunction with this embodiment or example are contained at least one embodiment of the present utility model.In this manual, identical embodiment is not necessarily referred to the schematic representation of above-mentioned term.And the specific features of description, structure, material or feature can combine in an appropriate manner in any one or more embodiments.

Although illustrate and described embodiment of the present utility model, those having ordinary skill in the art will appreciate that: can carry out multiple change, amendment, replacement and modification to these embodiments when not departing from principle of the present utility model and aim, scope of the present utility model is by claim and equivalents thereof.

Claims (12)

1. for a guiding subassembly for electric heater, it is characterized in that, comprising:

Deflector, described deflector is provided with impact-absorbing shell pilot hole and the water outlet flow-guiding channel of upper space and the lower space being communicated with described deflector respectively;

Water inlet impact-absorbing shell, described water inlet impact-absorbing shell is arranged in described impact-absorbing shell pilot hole, and described water inlet impact-absorbing shell is provided with the cover body water inlet be communicated with described upper space and the cover body delivery port be communicated with described lower space.

2. the guiding subassembly for electric heater according to claim 1, is characterized in that, described deflector is provided with outlet pipe locating hole and the magnesium rod locating hole of through described deflector respectively.

3. the guiding subassembly for electric heater according to claim 1, is characterized in that, described deflector comprises:

Plate body, described impact-absorbing shell pilot hole is located on described plate body;

Edge, some sides, some described sides are along being connected with the edge of described plate body respectively and extending to described lower space, and described water outlet flow-guiding channel is located at described plate body and/or described side along upper.

4. the guiding subassembly for electric heater according to claim 3, is characterized in that, described water outlet flow-guiding channel comprises:

Water outlet relief hole, described water outlet relief hole is located on described plate body; And/or

Water outlet guiding gutter, described water outlet guiding gutter is located at described side along upper.

5. the guiding subassembly for electric heater according to claim 3, is characterized in that, described side is along being of a size of 5-15 millimeter in the vertical direction.

6. the guiding subassembly for electric heater according to claim 1, is characterized in that, the upper surface of described water inlet impact-absorbing shell is higher than the upper surface of described deflector.

7. the guiding subassembly for electric heater according to any one of claim 1-6, is characterized in that, described water inlet impact-absorbing shell comprises:

Cover body, described cover body is arranged in described impact-absorbing shell pilot hole, on the upper surface that described cover body water inlet is located at described cover body and the lower surface of described cover body open wide to form described cover body delivery port;

Labyrinth structure, described labyrinth structure is located in described cover body, and the lower surface of described labyrinth structure is lower than the lower surface or concordant with the lower surface of described cover body of described cover body.

8. the guiding subassembly for electric heater according to claim 7, it is characterized in that, described labyrinth structure comprises multiple arc, on the inner roof wall face that multiple described arc is connected to described cover body and be distributed in described cover body water inlet concentric arrange circumferentially multiple, arc circumferentially described in each along the circumferential interval of described cover body water inlet arrange and adjacent described in arc circumferentially to stagger in the circumference of described cover body water inlet setting.

9. the guiding subassembly for electric heater according to claim 7, is characterized in that, described labyrinth structure comprises:

Multiple arc, on the inner roof wall face that multiple described arc is connected to described cover body and be distributed in described cover body water inlet concentric arrange circumferentially multiple, arc circumferentially described in each along the circumferential interval of described cover body water inlet arrange and adjacent described in arc circumferentially to stagger in the circumference of described cover body water inlet setting, the lower surface of described arc is lower than the lower surface of described cover body;

Screens, described screens to be located at below described cover body and around multiple described arc.

10. the guiding subassembly for electric heater according to claim 9, is characterized in that, described screens is made up of some layers of stainless (steel) wire, and the aperture of every layer of described stainless (steel) wire is 50-300 order.

11. guiding subassemblies for electric heater according to claim 7, it is characterized in that, described labyrinth structure comprises:

Multiple arc, on the inner roof wall face that multiple described arc is connected to described cover body and be distributed in described cover body water inlet concentric arrange circumferentially multiple, arc circumferentially described in each along the circumferential interval of described cover body water inlet arrange and adjacent described in arc circumferentially to stagger in the circumference of described cover body water inlet setting, the lower surface of described arc is lower than the lower surface of described cover body;

Sleeve, described sleeve to be located at below described cover body and around multiple described arc, and the lower surface of described sleeve is higher than the lower surface or concordant with the lower surface of described arc of described arc.

12. 1 kinds of electric heaters, is characterized in that, comprising:

Inner bag, described inner bag is provided with water inlet pipe and outlet pipe;

Guiding subassembly, described guiding subassembly is the guiding subassembly for electric heater according to any one of claim 1-11, described guiding subassembly is located in described inner bag, one end of described water inlet pipe is stretched into described upper space and is communicated with the cover body water inlet of described water inlet impact-absorbing shell, and described upper space is stretched in one end of described outlet pipe.