CN204922091U - Push type control valve is stabilized to temperature - Google Patents

Abstract

The utility model provides a push type control valve is stabilized to temperature, includes pressing piece, rotation piece, magnet frame, annular magnet, spring, a water piece, a water bar, iron core, a flood peak, case lid, valve core case, valve gap, disk seat, temperature adjusting knob, temperature regulating part, main logical water spare, logical water spare (a), logical water spare (b), logical water spare (c), constant temperature equipment, press the pressing piece makes the pressing piece is when shifting up the state, under hydraulic effect it reaches to seal the water piece seal the water bar and together shift up, thereby opened on the valve core case the delivery port, press under above -mentioned state the pressing piece makes the pressing piece is when moving down the state, under hydraulic effect it reaches to seal the water piece seal the water bar and together move down, thereby closed on the valve core case the delivery port, work as the rotation during the temperature adjusting knob, it makes to seal water portion go up and lead to on the water spare first inlet opening is the grow gradually the second inlet opening diminishes gradually, flow when the warp when the water pressure of first intake chamber reduces, the rivers of second intake chamber promote on the smooth core of constant temperature the pressure balance face makes the smooth core of constant temperature to first logical basin slides.

Description

Water temperature stability push type control valve

Technical field

The utility model relates to a kind of valve, particularly a kind of water temperature stability push type control valve.

Background technique

CN202158209U has disclosed a kind of soft-touch type tap valve core, and CN102072361A has disclosed a kind of spool for sanitary equipment; In the cold and hot mixing water situation of use, when other water tap of family uses cold water, mixing water can heating.

Model utility content

The purpose of this utility model is to provide a kind of water temperature stability push type control valve, as long as moving up and down of the pressing member on control valve top just can be opened or close outlet valve.

To achieve these goals, the water temperature stability push type control valve that the utility model provides, is characterized in that: comprise pressing member, rotating component, magnet frame, ring magnet, spring, water sealing slice, water shutoff bar, iron core, water shutoff head, cartridge cover, valve core case, valve gap, valve seat, lower water temperature button, lower water temperature part, main water flowing part, water flowing part (a), water flowing part (b), water flowing part (c), constant temperature device;

Wherein, described pressing member has guiding convex with guiding tooth, described rotating component has rotate convex and turning gear, described magnet frame has spring positioning part and ring magnet fixed position;

Wherein, described water sealing slice there is connection aperture, described water shutoff bar has control hole; , described valve core case there are water intake, water outlet, water sealing slice position in cored chamber in described cartridge cover;

Wherein, described valve gap has transmission foot groove, pressing piece bores is arranged at top, and internal upper part has rotation tongue, guiding tongue, the first inclined-plane, the second inclined-plane; Described rotation tongue is darker than described guiding tongue, and described rotation is convex can only put into described rotation tongue and can not put into described guiding tongue; Described valve seat there are the first water inlet, the second water inlet, osculum, water flowing chamber;

Wherein, described lower water temperature button there is transmission foot, described lower water temperature part has spool bore, water flowing chamber, water shutoff portion, transmission foot position; Described main water flowing part there are spool bore, the first water inlet, the second water inlet, water-flowing trough; Described water flowing part has the first water inlet, the second water inlet, osculum, water flowing chamber;

Wherein, described constant temperature device comprises constant temperature base, a pair constant temperature seat, constant temperature core, constant temperature slide core; Described constant temperature base there are osculum, constant temperature bore; Described constant temperature seat there are water inlet, constant temperature core bore; Described constant temperature core there are the first water-flowing trough, the second water-flowing trough, slip core hole; Described constant temperature slide core has the first intake chamber, the second intake chamber, pressure balance face, the first retaining section, the second retaining section, described pressure balance face is between described first intake chamber and described second intake chamber; In the described slip core hole of described constant temperature slide core on described constant temperature core, and described first water-flowing trough of a part is blocked in described first retaining section, and described second water-flowing trough of a part is blocked in described second retaining section, in the described constant temperature core bore of described constant temperature core on constant temperature seat described in a pair, in the described constant temperature bore of described constant temperature seat on described constant temperature base;

Described water flowing part (a), described constant temperature device, described water flowing part (b), described water flowing part (c), described main water flowing part, described lower water temperature part are arranged in described valve seat successively; Described first water inlet on described water flowing part (a) is relative with described first water inlet on described valve seat, and the second water inlet in them is also relative; Described osculum on described constant temperature base in described constant temperature device is connected with the described osculum on described water flowing part (a); Described osculum on described water flowing part (b) is connected with the described osculum on the described constant temperature base in described constant temperature device; Described osculum on described water flowing part (c) is relative with the described osculum of described water flowing part (b); Described first water inlet on described main water flowing part is relative with described first water inlet on described water flowing part (c), and the second water inlet in them is also relative; Described first intake chamber in described constant temperature slide core is communicated with described first water inlet on described water flowing part (b), described water flowing part (a), and described second intake chamber in described constant temperature slide core is communicated with described second water inlet on described water flowing part (b), described water flowing part (a);

Described water sealing slice is on described water shutoff bar, and described water shutoff head is fixed on the lower end of described iron core, and described ring magnet is in described magnet frame; Described valve core case is on described lower water temperature part, described water sealing slice and described water shutoff bar are on described valve core case, described cartridge cover, on described water sealing slice, wherein makes described water shutoff head towards in the described iron core chamber of the described control hole on described water shutoff bar in described cartridge cover with the described iron core of described water shutoff head; With the described magnet frame of described ring magnet in described cartridge cover and described ring magnet outside described iron core, between described magnet frame and described cartridge cover, have described spring;

One end of described pressing member is stretched out described in described valve upper part of the cover and is pressed piece bores, in the convex described rotation tongue at described valve gap internal upper part of the described guiding on described pressing member, described guiding tongue; Described rotating component is between described pressing member and described magnet frame, and described valve gap is fixed on described valve seat;

Described lower water temperature button is enclosed within described valve gap, and the described transmission foot on described lower water temperature button extend on the described transmission foot position on described lower water temperature part by the described transmission foot groove on described valve gap;

When described pressing member is raised state, in the convex described rotation tongue on described valve gap of described rotation on described rotating component, described pressing member is made to move down in this condition, described pressing member promotes described rotating component and moves down, when moving down into certain position, described rotation is convex skids off described rotation tongue, due to the effect of described spring, described turning gear slides into bottom described first inclined-plane below described guiding tongue along described first inclined-plane along slipping into described first inclined-plane after described guiding tooth rotates a little again; Now described pressing member is lower shifting state;

Described pressing member is moved down again when described pressing member is lower shifting state, due to the effect of described spring, described turning gear slides into bottom described second inclined-plane along described second inclined-plane more finally slip in described rotation tongue along slipping into described second inclined-plane after described guiding tooth rotates a little, thus makes described pressing member moves; Described pressing member is finally made to be raised state;

When there being current to enter, press described pressing member when making described pressing member be raised state, due to the effect of described spring, described magnet frame makes described rotating component and described pressing member move, described ring magnet make described iron core also on move, described water shutoff head leaves the described control hole on described water shutoff bar, thus opens described control hole, under the effect of hydraulic pressure described water sealing slice and described water shutoff bar together on move, thus open the described water outlet on described valve core case;

Press described pressing member in the above-described state when making described pressing member be lower shifting state, described pressing member makes described rotating component and described magnet frame move down, described ring magnet drives described iron core to move down, described water shutoff head moves down the described control hole withstood on described water shutoff bar, under the effect of hydraulic pressure, described water sealing slice and described water shutoff bar together move down, thus close the described water outlet on described valve core case;

When rotating described lower water temperature button, the described transmission foot on described lower water temperature button drives described lower water temperature part to rotate, and described water shutoff portion makes described first water inlet on described upper water flowing part gradually become described greatly the second water inlet gradually to diminish;

Described water outlet on described valve core case opens described first intake chamber, described second intake chamber have current through and hydraulic pressure through flowing described second intake chamber is constant, when the hydraulic pressure through flowing described first intake chamber reduces, described pressure balance face in constant temperature slide core described in the water jet propulsion of described second intake chamber makes described constant temperature slide core slide to described first water-flowing trough, make described first retaining section decrease stop to described first water-flowing trough, and make described second retaining section increase stop to described second water-flowing trough.

The beneficial effects of the utility model are:

What only need the pressing member on control valve top gently moves up and down the unlatching or closedown that just can control outlet valve, and in the cold and hot mixing water situation of use, when other water tap of family uses cold water, mixing water can not heating.

Accompanying drawing explanation

Fig. 1 is pressing member schematic diagram of the present utility model.

Fig. 2 is rotating component schematic diagram of the present utility model.

Fig. 3 is magnet frame schematic diagram of the present utility model.

Fig. 4 is ring magnet schematic diagram of the present utility model.

Fig. 5 is spring schematic diagram of the present utility model.

Fig. 6 is water shutoff spring schematic diagram of the present utility model.

Fig. 7 (a) is water sealing slice schematic diagram of the present utility model.

Fig. 7 (b) is water sealing slice generalized section of the present utility model.

Fig. 8 (a) is water shutoff bar schematic diagram of the present utility model.

Fig. 8 (b) is water shutoff bar generalized section of the present utility model.

Fig. 9 is lower water temperature lid schematic diagram of the present utility model.

Figure 10 is lower water temperature button schematic diagram of the present utility model.

Figure 11 (a) is cartridge cover schematic diagram of the present utility model.

Figure 11 (b) is cartridge cover generalized section of the present utility model.

Figure 12 (a) is valve core case schematic diagram of the present utility model.

Figure 12 (b) is valve core case generalized section of the present utility model.

Figure 13 (a) is valve gap schematic diagram of the present utility model.

Figure 13 (b) is valve gap generalized section of the present utility model.

Figure 14 (a) is valve seat schematic top plan view of the present utility model.

Figure 14 (b) is that valve seat of the present utility model faces upward schematic side view.

Figure 15 is energizing spring schematic diagram of the present utility model.

Figure 16 is iron core schematic diagram of the present utility model.

Figure 17 is water shutoff head schematic diagram of the present utility model.

Figure 18 (a) is lower water temperature part front schematic view of the present utility model.

Figure 18 (b) is lower water temperature part reverse side schematic diagram of the present utility model.

Figure 19 is main water flowing part schematic diagram of the present utility model.

Figure 20 is water flowing part schematic diagram of the present utility model.

Figure 21 is constant temperature base schematic diagram of the present utility model.

Figure 22 (a) is constant temperature seat (a) schematic diagram of the present utility model.

Figure 22 (b) is constant temperature seat (b) schematic diagram of the present utility model.

Figure 23 is constant temperature core schematic diagram of the present utility model.

Figure 24 is constant temperature slide core schematic diagram of the present utility model.

Figure 25 (a) is constant temperature device schematic diagram of the present utility model.

Figure 25 (b) is constant temperature device generalized section of the present utility model.

Figure 26 is the generalized section of the utility model under valve port open mode.

Figure 27 is the generalized section of the utility model under valve port closed condition.

Embodiment

Consult Fig. 1, pressing member 1 has guiding convex 2 and guiding tooth 3;

Consult Fig. 2, rotating component 4 has and rotates convex 5 and turning gear 6;

Consult Fig. 3, magnet frame 7 has spring positioning part 8 and ring magnet fixed position 9;

Consult Fig. 7 (a), Fig. 7 (b), water sealing slice 13 has and is communicated with aperture 14;

Consult Fig. 8 (a), Fig. 8 (b), water shutoff bar 15 has control hole 16, water port 17;

Consult Fig. 9, lower water temperature lid 18 has transmission convex 19;

Consult Figure 10, lower water temperature button 20 has transmission foot 21, driving convex position 22;

Consult Figure 11 (a), Figure 11 (b), cored chamber 24 in cartridge cover 23;

Consult Figure 12 (a), Figure 12 (b), valve core case 25 has water intake 26, water outlet 27, water sealing slice position 28;

Consult Figure 13 (a), Figure 13 (b), valve gap 29 has transmission foot groove 30, pressing piece bores 31 is arranged at top, and internal upper part has rotation tongue 32, guiding inclined-plane 35, tongue 33, first inclined-plane 34, second; Rotate tongue 32 darker than guiding tongue 33, rotate convex 5 and can only put into rotation tongue 32 and guiding tongue 33 can not be put into;

Consult Figure 14 (a), Figure 14 (b), valve seat 36 has the first water inlet 39, water inlet 38, second, osculum 40;

Consult Figure 18 (a), Figure 18 (b), lower water temperature part 46 has spool bore 47, water flowing chamber 48, water shutoff portion 49, transmission foot position 50;

Consult Figure 19, main water flowing part 51 has water inlet 39, spool bore 47, first water inlet 38, second, water-flowing trough 52;

Consult Figure 20, water flowing part 53 has the first water inlet 39, water inlet 38, second, osculum 40;

Consult Figure 21, constant temperature base 54 has osculum 40, constant temperature bore 55;

Consult Figure 22 (a), Figure 22 (b), constant temperature seat 56 has water inlet 57, constant temperature core bore 58;

Consult Figure 23, constant temperature core 59 has the first water-flowing trough 60, second water-flowing trough 61, slip core hole 62;

Consult Figure 24, constant temperature slide core 63 has the first intake chamber 64, second intake chamber 65, retaining section 68, retaining section 67, second, pressure balance face 66, first, pressure balance face 66 is between the first intake chamber 64 and the second intake chamber 65.

Consult Figure 22 (a) to Figure 25 (b), in the slip core hole 62 of constant temperature slide core 63 on constant temperature core 59, and the first water-flowing trough 60 of a part is blocked in the first retaining section 67, and the second water-flowing trough 61 of a part is blocked in the second retaining section 68, in the constant temperature core bore 58 of constant temperature core 59 on a pair constant temperature seat 56, in the constant temperature bore 55 of constant temperature seat 56 on constant temperature base 54; So just be assembled into a set of constant temperature device;

Consult Figure 14 (a), Figure 14 (b), Figure 18 (a) is to Figure 26, and water flowing part 53 (a), constant temperature device, water flowing part 53 (b), water flowing part 53 (c), main water flowing part 51, lower water temperature part 46 are arranged in valve seat 36 successively; The first water inlet 38 on water flowing part 53 (a) is relative with the first water inlet 38 on valve seat 36, and the second water inlet 39 in them is also relative; Osculum 40 on constant temperature base 54 in constant temperature device is connected with the osculum 40 on water flowing part 53 (a); Osculum 40 on water flowing part 53 (b) is connected with the osculum 40 on the constant temperature base 54 in constant temperature device; Osculum 40 on water flowing part 53 (c) is relative with the osculum 40 of water flowing part 53 (b); The first water inlet 38 in main water flowing 51 is relative with the first water inlet 38 on water flowing part 53 (c), and the second water inlet 39 in them is also relative; The first intake chamber 64 in constant temperature slide core 63 is communicated with the first water inlet 38 on water flowing part 53 (b), water flowing part 53 (a), and the second intake chamber 65 in constant temperature slide core 63 is communicated with the second water inlet 39 on water flowing part 53 (b), water flowing part 53 (a);

Consult Fig. 3 to Fig. 8 (b), Figure 11 (a) is to Figure 12 (b), Figure 15 to Figure 17, Figure 26, water sealing slice 13 is on water shutoff bar 15, and water shutoff 43 is fixed on the lower end of iron core 42, and ring magnet 10 is on the ring magnet fixed position 9 of magnet frame 7; Valve core case 25 is on lower water temperature part 46, water sealing slice 13 and water shutoff bar 15 are on the water sealing slice position 28 of valve core case 25, cartridge cover 23 is on water sealing slice 13, wherein make water shutoff 43 towards in the iron core chamber 24 of the control hole 16 on water shutoff bar 15 in cartridge cover 23 with the iron core 42 of water shutoff 43, and energizing spring 41 is had between iron core 42 and top, iron core chamber 24, between water shutoff bar 15 and cartridge cover 23, there is water shutoff spring 12; With the magnet frame 7 of ring magnet 10 in cartridge cover 23 and ring magnet 10 outside iron core 42, between magnet frame 7 and cartridge cover 23, have spring 11;

Consult Fig. 1, Fig. 2, Fig. 3, Figure 13 (a) to Figure 14 (b), the pressing piece bores 31 on valve gap 29 top is stretched out in one end of pressing member 1, and the guiding on pressing member 1 convex 2 is in the rotation tongue 32 and guiding tongue 33 of valve gap 29 internal upper part; Rotating component 4 is between pressing member 1 and magnet frame 7, and valve gap 29 is fixed on valve seat 36;

Consult Fig. 9, Figure 10, Figure 13 (a) to, 14 (a), Figure 26, lower water temperature button 20 is enclosed within valve gap 29, transmission foot 21 on lower water temperature button 20 extend on the transmission foot position 50 on lower water temperature part 46 by the transmission foot groove 30 on valve gap 29, lower water temperature lid 18 on lower water temperature button 20, on the driving convex position 22 of the transmission on lower water temperature lid 18 convex 19 on lower water temperature button 20.

The structure of pressing member 1, rotating component 4, valve gap 29 internal upper part is exactly the structure of the sliding bouncing type pen core that we often use at ordinary times in fact, is early known technology, to make brief of the introduction their working procedure below in conjunction with accompanying drawing;

Consult Fig. 1, Fig. 2, Figure 13 (a), Figure 13 (b), when pressing member 1 is in raised state, in the rotation tongue 32 of rotation on rotating component 4 convex 5 on valve gap 29, pressing member 1 is made to move down in the above-described state, pressing member 1 promotes rotating component 4 and moves down, rotate convex 5 when moving down into certain position and skid off rotation tongue 32, due to the effect of spring 11, turning gear 6 slides into bottom the first inclined-plane 34 of leading below tongue 33 along slipping into the first inclined-plane 34 after guiding tooth 3 rotates a little again along the first inclined-plane 34; Now pressing member 1 is in lower shifting state; Pressing member 1 is moved down again when above-mentioned state, due to the effect of spring 11, turning gear 6 slides into along the second inclined-plane 35 more finally to slip in rotation tongue 32 bottom the second inclined-plane 35 along slipping into the second inclined-plane 35 after guiding tooth 3 rotates a little, thus make pressing member 1 moves, pressing member 1 is in raised state;

The structure of water sealing slice 13, water shutoff bar 15, iron core 42, water shutoff 43 is exactly similar with the valve core structure in existing solenoid valve in fact, and its opening and closing principle is early known technology, to make brief of the introduction their working procedure below in conjunction with accompanying drawing;

Consult Fig. 3 to Fig. 8 (b), Figure 11 (a) is to Figure 12 (b), Figure 15 to Figure 17, Figure 26, Figure 27, when there being current to enter, press lower water temperature lid 18, when making pressing member 1 in raised state, due to the effect of spring 11, magnet frame 7 and rotating component 4 and pressing member 1 all on move, ring magnet 10 also on move, ring magnet 10 make iron core 42 also on move, the control hole 16 on water shutoff bar 15 is left in water shutoff 43, thus open control hole 16, water sealing slice 13 and water shutoff bar 15 1 is the same moves under the effect of hydraulic pressure, thus the water outlet 27 opened on valve core case 25, press lower water temperature lid 18 in the above-described state, when making pressing member 1 in lower shifting state, pressing member 1 makes rotating component 4 and magnet frame 7 move down, ring magnet 10 drives iron core 42 to move down, water shutoff 43 moves down the control hole 16 withstood on water shutoff bar 15, under the effect of hydraulic pressure, water sealing slice 13 and water shutoff bar 15 together move down, thus close the water outlet 27 on valve core case 25,

Consult Fig. 9, Figure 10, Figure 18 (a) to Figure 19, Figure 10, when rotating lower water temperature lid 18, transmission convex 19 drives lower water temperature button 20 to rotate, transmission foot 21 on lower water temperature button 20 drives lower water temperature part 46 to rotate, and water shutoff portion 49 makes the first water inlet 38 on water flowing part 51 gradually become large second water inlet 39 gradually to diminish;

Consult Figure 14 (a), Figure 14 (b), Figure 18 (a) is to Figure 26, water outlet 27 on valve core case 25 opens the first intake chamber 64 in constant temperature slide core 63, second intake chamber 65 have current through and hydraulic pressure through flowing the second intake chamber 65 is constant when, when the hydraulic pressure through flowing the first intake chamber 64 reduces, pressure balance face 66 in water jet propulsion constant temperature slide core 63 through flowing the second intake chamber 65 makes constant temperature slide core 63 slide to the first water-flowing trough 60 on constant temperature core 59, the first retaining section 67 is made to decrease stop to the first water-flowing trough 60, and make the second retaining section 68 increase stop to the second water-flowing trough 61, if be hot water be that is cold water through what flow the first intake chamber 64 through what flow the second intake chamber 65, when other water tap of family uses cold water, the pressure of the water through flowing the first intake chamber 64 can reduce, in this case, constant temperature slide core 63 is slided, and makes the first water-flowing trough 60 opening increase the second water-flowing trough 61 opening and reduces thus the temperature constant making the mixing water flowed out from water outlet 27.

Claims (1)

1. a water temperature stability push type control valve, is characterized in that: comprise pressing member, rotating component, magnet frame, ring magnet, spring, water sealing slice, water shutoff bar, iron core, water shutoff head, cartridge cover, valve core case, valve gap, valve seat, lower water temperature button, lower water temperature part, main water flowing part, water flowing part (a), water flowing part (b), water flowing part (c), constant temperature device;

Wherein, described pressing member has guiding convex with guiding tooth, described rotating component has rotate convex and turning gear, described magnet frame has spring positioning part and ring magnet fixed position;

Wherein, described water sealing slice there is connection aperture, described water shutoff bar has control hole; , described valve core case there are water intake, water outlet, water sealing slice position in cored chamber in described cartridge cover;

Wherein, described valve gap has transmission foot groove, pressing piece bores is arranged at top, and internal upper part has rotation tongue, guiding tongue, the first inclined-plane, the second inclined-plane; Described rotation tongue is darker than described guiding tongue, and described rotation is convex can only put into described rotation tongue and can not put into described guiding tongue; Described valve seat there are the first water inlet, the second water inlet, osculum, water flowing chamber;

Wherein, described lower water temperature button there is transmission foot, described lower water temperature part has spool bore, water flowing chamber, water shutoff portion, transmission foot position; Described main water flowing part there are spool bore, the first water inlet, the second water inlet, water-flowing trough; Described water flowing part has the first water inlet, the second water inlet, osculum, water flowing chamber;

Wherein, described constant temperature device comprises constant temperature base, a pair constant temperature seat, constant temperature core, constant temperature slide core; Described constant temperature base there are osculum, constant temperature bore; Described constant temperature seat there are water inlet, constant temperature core bore; Described constant temperature core there are the first water-flowing trough, the second water-flowing trough, slip core hole; Described constant temperature slide core has the first intake chamber, the second intake chamber, pressure balance face, the first retaining section, the second retaining section, described pressure balance face is between described first intake chamber and described second intake chamber; In the described slip core hole of described constant temperature slide core on described constant temperature core, and described first water-flowing trough of a part is blocked in described first retaining section, and described second water-flowing trough of a part is blocked in described second retaining section, in the described constant temperature core bore of described constant temperature core on constant temperature seat described in a pair, in the described constant temperature bore of described constant temperature seat on described constant temperature base:

Described water flowing part (a), described constant temperature device, described water flowing part (b), described water flowing part (c), described main water flowing part, described lower water temperature part are arranged in described valve seat successively; Described first water inlet on described water flowing part (a) is relative with described first water inlet on described valve seat, and the second water inlet in them is also relative; Described osculum on described constant temperature base in described constant temperature device is connected with the described osculum on described water flowing part (a); Described osculum on described water flowing part (b) is connected with the described osculum on the described constant temperature base in described constant temperature device; Described osculum on described water flowing part (c) is relative with the described osculum of described water flowing part (b); Described first water inlet on described main water flowing part is relative with described first water inlet on described water flowing part (c), and the second water inlet in them is also relative; Described first intake chamber in described constant temperature slide core is communicated with described first water inlet on described water flowing part (b), described water flowing part (a), and described second intake chamber in described constant temperature slide core is communicated with described second water inlet on described water flowing part (b), described water flowing part (a);

Described water sealing slice is on described water shutoff bar, and described water shutoff head is fixed on the lower end of described iron core, and described ring magnet is in described magnet frame; Described valve core case is on described lower water temperature part, described water sealing slice and described water shutoff bar are on described valve core case, described cartridge cover, on described water sealing slice, wherein makes described water shutoff head towards in the described iron core chamber of the described control hole on described water shutoff bar in described cartridge cover with the described iron core of described water shutoff head; With the described magnet frame of described ring magnet in described cartridge cover and described ring magnet outside described iron core, between described magnet frame and described cartridge cover, have described spring;

One end of described pressing member is stretched out described in described valve upper part of the cover and is pressed piece bores, in the convex described rotation tongue at described valve gap internal upper part of the described guiding on described pressing member, described guiding tongue; Described rotating component is between described pressing member and described magnet frame, and described valve gap is fixed on described valve seat;

Described lower water temperature button is enclosed within described valve gap, and the described transmission foot on described lower water temperature button extend on the described transmission foot position on described lower water temperature part by the described transmission foot groove on described valve gap;

When described pressing member is raised state, in the convex described rotation tongue on described valve gap of described rotation on described rotating component, described pressing member is made to move down in this condition, described pressing member promotes described rotating component and moves down, when moving down into certain position, described rotation is convex skids off described rotation tongue, due to the effect of described spring, described turning gear slides into bottom described first inclined-plane below described guiding tongue along described first inclined-plane along slipping into described first inclined-plane after described guiding tooth rotates a little again; Now described pressing member is lower shifting state;

Described pressing member is moved down again when described pressing member is lower shifting state, due to the effect of described spring, described turning gear slides into bottom described second inclined-plane along described second inclined-plane more finally slip in described rotation tongue along slipping into described second inclined-plane after described guiding tooth rotates a little, thus makes described pressing member moves; Described pressing member is finally made to be raised state;

When there being current to enter, press described pressing member when making described pressing member be raised state, due to the effect of described spring, described magnet frame makes described rotating component and described pressing member move, described ring magnet make described iron core also on move, described water shutoff head leaves the described control hole on described water shutoff bar, thus opens described control hole, under the effect of hydraulic pressure described water sealing slice and described water shutoff bar together on move, thus open the described water outlet on described valve core case;

Press described pressing member in the above-described state when making described pressing member be lower shifting state, described pressing member makes described rotating component and described magnet frame move down, described ring magnet drives described iron core to move down, described water shutoff head moves down the described control hole withstood on described water shutoff bar, under the effect of hydraulic pressure, described water sealing slice and described water shutoff bar together move down, thus close the described water outlet on described valve core case;

When rotating described lower water temperature button, the described transmission foot on described lower water temperature button drives described lower water temperature part to rotate, and described water shutoff portion makes described first water inlet on described upper water flowing part gradually become described greatly the second water inlet gradually to diminish;

Described water outlet on described valve core case opens described first intake chamber, described second intake chamber have current through and hydraulic pressure through flowing described second intake chamber is constant, when the hydraulic pressure through flowing described first intake chamber reduces, described pressure balance face in constant temperature slide core described in the water jet propulsion of described second intake chamber makes described constant temperature slide core slide to described first water-flowing trough, make described first retaining section decrease stop to described first water-flowing trough, and make described second retaining section increase stop to described second water-flowing trough.