CN204784855U - Take decelerator's electronic diverter valve and use refrigerator system of this electronic diverter valve - Google Patents

Abstract

The utility model discloses a take decelerator's electronic diverter valve, including installing support, valve body part and stator part, stator part and installing support fixed connection, coil in the stator part with rotor part in the valve body part constitutes a step motor, its valve body part still includes valve casing, seat kits, slider subassembly, rotor part, spring and decelerator, the rotor part drives through this decelerator the slider subassembly slows down and rotates. The utility model also discloses an use the refrigerator system of this electronic diverter valve. The utility model discloses owing to adopted decelerator to transmit the power between rotor part and the slider subassembly, antitrochanter part and stator part require greatly reduced, be favorable to reducing the cost and the suitable batch manufacture of product. The utility model discloses an electronic diverter valve of original direct action type directly can be replaced to electronic diverter valve, has solved the poor noise difficult problem of switching -over reliability, and the high scheduling problem of manufacturing cost is fit for batch production.

Description

Dynamoelectric switching valve with speed reducer and use the refrigerator system of this dynamoelectric switching valve

Technical field

The utility model belongs to refrigeration technology, and refrigeration specifically, alternating temperature, deep freezer are with the dynamoelectric switching valve of speed reducer and use the refrigerator system of this dynamoelectric switching valve.

Background technique

Chinese patent notification number CN103016791B, CN100478596, CN101275678B, CN101270826B, CN101230928B, CN100478596C discloses several dynamoelectric switching valve, and they are all by with stator component drive motor rotor turns, and rotor is directly with movable slider to rotate, slide block relatively rotates with slide plate, slide block is provided with groove or hole or groove, when this groove or hole or groove aim at the valve port on slide plate, is connected to outer pipe on this hole with regard to conducting.Control slide block by the umber of pulse of control inputs stator component to rotate, realize being welded on the inlet tube on slide plate and switch with the break-make of two or more outer pipes.The dynamoelectric switching valve of the type requires high to rotor and stator, is unfavorable for the cost and the batch micro operations that reduce product.

Model utility content

For the deficiency that above-mentioned direct-acting type dynamoelectric switching valve exists, one of the purpose of this utility model is to having refrigeration, alternating temperature, and the refrigerator of freezing function provides high-performance, high energy saving, structure is simple, and reliability is high, interchangeability is good, and cost is low, is applicable to the dynamoelectric switching valve of batch production.

Two of the purpose of this utility model is to provide the refrigerator system using above-mentioned dynamoelectric switching valve.

To achieve these goals, the utility model is by the following technical solutions:

As the dynamoelectric switching valve of the band speed reducer of the utility model first aspect, comprising:

One mounting bracket, described mounting bracket inside has a receiving cavity;

One valve body parts, the Lower Half of described valve body parts is configured in described receiving cavity, and the inlet tube in described valve body parts and some outer pipes are through at the bottom of the chamber of described receiving cavity;

One is sleeved on the stator component on the first half of described valve body parts, and described stator component is fixedly connected with described mounting bracket, and the rotor part in the coil in described stator component and described valve body parts forms a stepper motor;

It is characterized in that, described valve body parts also comprises:

One valve casing, the one end open of described valve casing,

One valve component, described valve component comprises valve seat, inlet tube, some outer pipes, described valve seat is arranged on the aperture position of described valve casing, that being positioned at described valve casing at described valve seat is provided with a primary sealing area on the surface, a feed liquor via and some fluid vias is provided with in described valve seat, described feed liquor via and some fluid vias axially through whole valve seat, the outlet of wherein said feed liquor via be positioned at described valve casing that form liquid entering hole on the surface, a valve port is formed between the entrance of each fluid via and described primary sealing area, described inlet tube is connected with the entrance of described feed liquor via, and some outer pipes connect with the outlet of corresponding fluid via,

One to be configured on described valve component and to be positioned at the slide block assembly of described valve casing, described slide block assembly comprises a slide block, the side of the relatively described primary sealing area of described slide block is configured with secondary sealing area and at least one fluid groove, described secondary sealing area seals with primary sealing area and contacts, described fluid groove and described feed liquor via and the conducting respectively of some fluid vias; When in slide block rotation process, valve ports different on primary sealing area switches between described secondary sealing area and fluid groove, to open and close different valve ports;

One to be configured on described valve component and to be positioned at the rotor part of described valve casing;

One to be configured on described valve component and spring in described valve casing and between described rotor part and described slide block assembly, the first end of described spring withstands in the side of the relatively described spring of described slide block assembly, is pressed in by the secondary sealing area of described slide block on the primary sealing area of described valve seat;

One is configured in described valve component and is positioned at the speed reducer on described valve casing, and described rotor part drives described slide block assembly underdrive by this speed reducer.

In a preferred embodiment of the present utility model, described valve component also comprises a major axis and a minor axis, the first end of described major axis is arranged on the center that described valve seat is positioned at that surface of described valve casing, and the first end of described minor axis is arranged on described valve seat and is positioned at avris appropriate location outside the primary sealing area on that surface of described valve casing; Described major axis and minor axis parallel are arranged; Described slide block assembly, spring, rotor part are sleeved on described major axis, and described speed reducer is sleeved on described minor axis.

In a preferred embodiment of the present utility model, described valve body parts also comprises one and to be set on described major axis and to be positioned at the slipper bearing of described valve casing, and the side of the relatively described slide block assembly of described slipper bearing contacts with the side of opposing slider bearing in described slide block assembly; The first end of described spring withstands in the side of the relatively described spring of described slipper bearing, and is pressed on the primary sealing area of described valve seat by the secondary sealing area of described slide block by described slipper bearing.

In a preferred embodiment of the present utility model, described slide block assembly also comprises a driven gear, described driven gear is enclosed within described major axis, described slide block set is on described driven gear and between described driven gear and the primary sealing area of described valve seat, and described driven gear and described speed reducer engage each other.

In a preferred embodiment of the present utility model, be provided with tooth sector, reset locking plate in the outer rim of described driven gear, run locking plate, described in described tooth sector, speed reducer engages each other, described driven gear outer rim reset locking plate, run locking plate and contact with described speed reducer, to limit the rotation angle of driven gear in described slide block assembly and slide block.

In a preferred embodiment of the present utility model, it is the First Transition gear and the second transition gear that coaxially arrange that described speed reducer comprises, described First Transition gear and described rotor part engage each other, engaging each other from tooth sector in described second transition gear and described slide block assembly.

In a preferred embodiment of the present utility model, described valve body parts also comprises one and to be arranged on described minor axis second end and to be positioned at the spring sheet of described valve casing, described spring sheet contacts with the side of the relatively described spring sheet of described speed reducer, is axially limited on described minor axis by described speed reducer.

In a preferred embodiment of the present utility model, in the upper end outer rim of described rotor part, one multistage magnet ring is installed, that one end of the relatively described slide block assembly of described rotor part is configured with driving gear, and described driving gear and described First Transition gear engage each other.

In a preferred embodiment of the present utility model, rotor bearing mounting hole, rotary shaft hole and spring mounting hole is coaxially arranged with in described rotor part, described major axis is successively through described spring mounting hole, rotary shaft hole and rotor bearing mounting hole, second end of described major axis is bearing in described rotor bearing mounting hole by rotor bearing, and the second end of described spring to be inserted in described spring mounting hole and to withstand on the transitional surface of described spring mounting hole and described rotary shaft hole.

In a preferred embodiment of the present utility model, the Ke Di center of described valve casing is provided with a groove, the end of the second end of described major axis to be inserted in described groove and to withstand on the bottom land of described groove.

In a preferred embodiment of the present utility model, described fluid via is two, described outer pipe is also two and is separately fixed in corresponding fluid via, form the first valve port and the second valve port between two fluid vias and described primary sealing area respectively, described dynamoelectric switching valve can realize one of following four kinds of working staties:

First working state, described primary sealing area and secondary sealing area cooperatively interact and seal, and described feed liquor via and all valve ports are closed, and first and second valve port are also in closed condition each other;

Second working state, described feed liquor via is by described fluid groove and described second valve port conducting, but cooperatively interacted by described primary sealing area and secondary sealing area and seal, close between described feed liquor via and the first valve port, and first and second valve port is also in closed condition each other;

3rd working state, described feed liquor via by described fluid groove and first and second valve port conducting described, but is cooperatively interacted by described primary sealing area and secondary sealing area and seals, and first and second valve port is also in closed condition each other;

4th working state, described feed liquor via is by described fluid groove and described first valve port conducting, but cooperatively interacted by described primary sealing area and secondary sealing area and seal, close between described feed liquor via and the second valve port, and first and second valve port is also in closed condition each other.

In a preferred embodiment of the present utility model, described first working state, the second working state, the 3rd working state, the 4th working state are arranged or discontinuous setting continuously, but described first working state is corresponding with the initial position of described stepper motor.

As the refrigerator system of the utility model second aspect, comprise refrigeration plant, described refrigeration plant comprises compressor, device for drying and filtering, condenser, dynamoelectric switching valve, cold storage room capillary tube, refrigerator evaporator, refrigerating chamber capillary tube and freezer evaporator, wherein said dynamoelectric switching valve is the dynamoelectric switching valve of said structure, outer pipe in described dynamoelectric switching valve is two, be the first outer pipe and the second outer pipe, wherein, inlet tube in described dynamoelectric switching valve is connected with one end of described device for drying and filtering, the other end of described device for drying and filtering is connected with one end of described condenser, the other end of described condenser is connected by compressor one end with described freezer evaporator, the other end of described freezer evaporator is connected with one end of described refrigerating chamber capillary tube on the one hand, be connected with one end of described refrigerator evaporator on the other hand, the other end of described refrigerating chamber capillary tube is connected with described second outer pipe, the other end of described refrigerator evaporator is connected with described first outer pipe.

The utility model, owing to have employed speed reducer to transmit the power between rotor part and slide block assembly, reduces greatly to the requirement of rotor part and stator component, is conducive to reducing the cost of product and applicable batch micro operations.

The utility model is provided with a liquid inlet pipe and two outer pipes, can realize the open and close controlling to the refrigerating circuit of a refrigeration system Zhong Liangge branch by the control of stepper motor rotation angle.

The beneficial effects of the utility model are:

Dynamoelectric switching valve of the present utility model directly can replace original direct-acting type dynamoelectric switching valve, and solve a commutation poor reliability noise difficult problem, the problems such as manufacture cost is high, are applicable to batch production.

Accompanying drawing explanation

Fig. 1 is the axial sectional structure schematic diagram of dynamoelectric switching valve of the present utility model.

Fig. 2 is the axial sectional structure schematic diagram of valve body parts of the present utility model.

Fig. 3 is the worm's eye view of Fig. 2.

Fig. 4 is the axial sectional structure schematic diagram after valve seat in valve body parts of the present utility model, inlet tube, two outer pipes, major axis, minor axises assembling.

Fig. 5 is the plan view of Fig. 4.

Fig. 6 is the worm's eye view of Fig. 4.

Fig. 7 is the axial sectional structure schematic diagram of slide block assembly of the present utility model.

Fig. 8 is the worm's eye view of Fig. 7.

Fig. 9 is the worm's eye view of driven gear of the present utility model.

Figure 10 is the axial sectional structure schematic diagram of slide block of the present utility model.

Figure 11 is the plan view of Figure 10.

Figure 12 is the worm's eye view of Figure 10.

Figure 13 is the axial sectional structure schematic diagram of speed reducer of the present utility model.

Figure 14 is the plan view of spring sheet of the present utility model.

Figure 15 is the axial sectional structure schematic diagram of the utility model slipper bearing.

Figure 16 is the axial sectional structure schematic diagram of rotor bearing of the present utility model.

Figure 17 is the axial sectional structure schematic diagram of rotor part of the present utility model.

Figure 18 is mounting bracket schematic diagram of the present utility model.

Figure 19 is that a kind of dynamoelectric switching valve of the present utility model is applying different pulse number to stator, the schematic diagram of 4 kinds of on states of inlet tube and two outer pipes.

Figure 20 is the application schematic diagram of mortor operated valve of the present utility model inside refrigerator system.

Embodiment

Below in conjunction with Figure of description, the utility model is described in further details.

As shown in Figure 1, the dynamoelectric switching valve of the utility model band speed reducer is made up of three parts: valve body parts 100, stator component 200, mounting bracket 300.

As shown in figure 18, mounting bracket 300 is provided with three mounting bracket riveted joint 310, one, position small through hole, 320, large through-hole 330.

Composition graphs 1 and Figure 17, valve body parts 100 is riveted position 310 riveting with stator component 200 by three metal bosses 210 on stator component 200 and the mounting bracket of three on mounting bracket 300 and is connected.

As shown in Figures 2 and 3, valve body parts 100 is that slide block assembly 170 forms by valve casing 120, valve component 110, rotor bearing 130, rotor 140, spring 150, slipper bearing 160.Valve casing 120 is the tubular structure parts of band shoulder, and the tubular construction of its bottom opening, the bottom opening of this valve casing 120 is fixed on the valve seat 111 in valve component 110.

As shown in Figures 4 to 6, valve component 110 is welded by valve seat 111, inlet tube 112, outer pipe 113, outer pipe 114, minor axis 115, major axis 116; Valve seat 111 is equipped with minor axis mounting hole 111f, primary sealing area 111a, center hole 111b, feed liquor via 111c, fluid via 111e, fluid via 111d.Minor axis mounting hole 111f is positioned at the avris appropriate location outside primary sealing area 111a.

Feed liquor via 111c goes out interruption-forming liquid entering hole A, and entrance and the primary sealing area 111a of fluid via 111d form valve port B, and entrance and the primary sealing area 111a of fluid via 111e form valve port C.

One end of inlet tube 112 is welded in feed liquor via 111c also through with it, and one end of outer pipe 113 is welded in fluid via 111e also through with it, and one end of outer pipe 114 is welded in fluid via 111d also through with it.

In conjunction with referring to Fig. 1, inlet tube 112 through the small through hole 320 on mounting bracket 300, outer pipe 112, outer pipe 113 together through the large through-hole 330 on mounting bracket 300.The lower end of minor axis 115 is placed in minor axis mounting hole 111f, in centering hole, the lower end 111b of major axis 116.Major axis 116 and minor axis 115 be arranged in parallel.

As shown in Figure 7 and Figure 8, slide block assembly 170 is made up of driven gear 171 and slide block 172.In conjunction with see Fig. 9, the outer periphery of driven gear 171 are equipped with tooth sector 171f, reset locking plate 171b and run and stop locking plate 171a, a slipper bearing resettlement groove 171d is provided with at the center of the upper surface 171c of driven gear 171, a slide block erection column 171f is had in the center configuration of the lower surface 171e of driven gear 171, be provided with center hole 171g in slide block erection column 171f, center hole 171g and slipper bearing resettlement groove 171d is through.The lower surface 171e of driven gear 171 is also configured with three and protrudes pillar 171h, 171i, 171j.

As shown in Figure 10 to Figure 12, the center of slide block 172 is provided with center hole 172d, surperficial 172g is equipped with three attachment holes 172a, 172b, 172c thereon, its lower surface 172h is configured with secondary sealing area 172e and fluid groove 172f, the fan-shaped fluid groove of fluid groove 172f to be central angle be θ.

When slide block assembly 170 is assembled, on driven gear 171 three is protruded pillar 171h, 171i, 171j coordinate with three on slide block 172 attachment hole 172a, 172b, a 172c respectively, the slide block erection column 171f on driven gear 171 coordinates with the center hole 172d of slide block 172 makes them become to be integrated.

When slide block assembly 170 is sleeved on major axis 116, major axis 116 is through center hole 171g, the secondary sealing area 172e on slide block 172 and the primary sealing area 111a fitted seal on valve seat 111 in slide block erection column 171f.

As shown in figure 13, speed reducer 190 comprises First Transition gear 190b, external cylindrical surface 190f and the second transition gear 190c of coaxial setting, external cylindrical surface 190f is between First Transition gear 190b and the second transition gear 190c, First Transition gear 190b is gearwheel, and the second transition gear 190c is small gear.Offer a central bore 190d at the center of speed reducer 190, central bore 190d runs through upper surface 190a and the lower surface 190e of speed reducer 190.

As shown in figure 14, spring sheet 180 is equipped with three elastic pressuring plate 180a, 180b, 180c and top plane 180d.

During assembling, the central bore 190d of speed reducer 190 is inserted on minor axis, spring sheet 180 is fixed on (see Fig. 4) on the upper plane 115a of minor axis 115, the upper plane 190a of speed reducer 190 compresses by three elastic pressuring plate 180a, 180b, 180c on spring sheet 180, and speed reducer 190 can do rotation motion.

As shown in figure 15, be equipped with endoporus 160a in slipper bearing 160, outer rim is equipped with external cylindrical surface 160b, step surface 160c, lower plane 160d.Wherein external cylindrical surface 160b and step surface plane 160c forms spring seat, endoporus 160a is enclosed within major axis 116, convex shoulder 160e between lower plane 160d and step surface 160c is placed in the slipper bearing resettlement groove 171d of driven gear 171, lower plane 160d is close to the bottom land of slipper bearing resettlement groove 171d, and the primary sealing area 111a of the valve seat 111 in the secondary sealing area 172h of slide block 172 in slide block assembly 170 and valve component 110 is fitted tightly.

As shown in figure 16, be provided with central bore 130d in rotor bearing 130, central bore 130d runs through upper plane 130a and the lower plane 130e of rotor bearing 130, and the outer rim of rotor bearing 130 is provided with convex shoulder 130b and external cylindrical surface 130c.

As shown in figure 17, one multistage magnet ring 140h is installed on the outer rim top of rotor assembly 140, bearing mounting hole 140b, rotary shaft hole 140c and spring mounting hole 140f is from top to bottom disposed with in rotor part 140, an inner cylindrical surface 140e is configured with in the outer rim of rotary shaft hole 140c, be provided with a midplane 140d between the root of inner cylindrical surface 140e and the root of spring mounting hole 140f, inner cylindrical surface 140e and midplane 140d forms a rotor spring seat.Driving gear 140g is configured with in the outer rim lower end of rotor part 140

During assembling, the external cylindrical surface 130c of rotor bearing 130 is pressed in the bearing mounting hole 140b of rotor assembly 140, the convex shoulder 130b bottom surface of axle rotor bearing 160 and the upper plane 140a of rotor assembly 140 fit, rotor assembly 140 is inserted in the top of major axis 116, the upper end of major axis 116 and the central bore 130d of rotor bearing 130 are rotatably assorted, major axis 116 is rotatably assorted with the rotary shaft hole 140c of rotor assembly 140 simultaneously, the upper end being enclosed within the spring 150 on major axis 116 to be enclosed within rotor spring seat and to be against on midplane 140d, lower end is enclosed within the external cylindrical surface 160b of slipper bearing 160 and is against on step surface plane 160c.Driving gear 140g on the rotor assembly 140 and First Transition gear 190b on speed reducer 190 engages, and the second transition gear 190c on speed reducer 190 engages with the tooth sector 171f on the driven gear 171 in slide block assembly 170.

Composition graphs 2, is provided with a groove 121 at the Ke Di center of valve casing 120, and the end of the upper end of major axis 116 to be inserted in groove 121 and to withstand on the bottom land of groove 121.

To the coil input pulse electric current in stator component 200, rotor assembly 140 is driven to rotate, driving gear 140g in rotor assembly 140 rotates, by with the engaging of First Transition gear 190b, drive speed reducer 190 to rotate, the rotation of speed reducer 190, the second transition gear 190c is driven to rotate, second transition gear 190c, by engagement, drives the driven gear 171 in slide block assembly 170 to rotate, thus drives the slide block 172 in slider part 170 to relatively rotate.

When the slide block 172 in slider part 170 turns to several angle, the fluid groove 172f be arranged on slide block 172 targeted by liquid entering hole A, valve port B or valve port C on valve seat 111, outer pipe 113,114 conducting that inlet tube 112 is just corresponding with it, otherwise for closing, form an inlet passage and two outlet passages thus.

As shown in figure 19, apply different umber of pulses to stator component 200, four kinds of working staties can be realized, specifically:

A, applying reset pulse (start bit), and then apply 34 pulses, slide block 172 in slide block assembly 170 rotates 51 degree with rotor assembly 140, slide block 172 in slider part 170 turns to initial position with rotor assembly 140, now fluid groove 172f not targeted by valve port B, the valve port C on valve seat 111, closes and close between valve port B, valve port C yet between liquid entering hole A and valve port B, valve port D;

B, apply 66 pulses again, slide block 172 in slider part 170 rotates 99 degree with rotor assembly 140, and now fluid groove 172f targeted by the valve port C on valve seat 111, liquid entering hole A and valve port C conducting, but with valve port B not conducting, and also close between valve port B, valve port C;

C, apply 54 pulses again, the slide block 172 in slider part 170 rotates 81 degree with rotor assembly 140, and now fluid groove 172f targeted by valve port C, the valve port B on valve seat 111, liquid entering hole A and valve port C, valve port B conducting, and also conducting between valve port B, valve port C;

D, apply 41 pulses again, slide block 172 in slider part 170 rotates 61.5 degree with rotor assembly 140, and now fluid groove 172f targeted by the valve port B on valve seat 111, liquid entering hole A and valve port B conducting, but with valve port C not conducting, and also close between valve port B, valve port C;

In addition can by changing the position of fluid groove 172f and the size of θ angle of the slide block 172 in slider part 170, achieved multiple inlet tube and the break-make of outer pipe combine, and can meet the diversified functional need of user.In like manner also can combine the break-make of the more abundant inlet tube of the umber of pulse realization of stator component and outer pipe by changing according to the usage requirement of user.

See Figure 20, the refrigeration plant of the refrigerator system provided in figure comprises compressor 400, device for drying and filtering 500, condenser 600, dynamoelectric switching valve 700, cold storage room capillary tube 800, refrigerator evaporator 900, refrigerating chamber capillary tube 1000 and freezer evaporator 1100, and wherein dynamoelectric switching valve 700 is the dynamoelectric switching valve of said structure.Outer pipe in dynamoelectric switching valve is two, for outer pipe B and C, inlet tube is one, for inlet tube A, inlet tube A in dynamoelectric switching valve is connected with one end of device for drying and filtering 500, the other end of device for drying and filtering 500 is connected with one end of condenser 600, the other end of condenser 600 is connected with one end of freezer evaporator 900 by compressor 400, the other end of freezer evaporator 900 is connected with one end of refrigerating chamber capillary tube 1000 on the one hand, be connected with one end of refrigerator evaporator 1100 on the other hand, the other end of refrigerating chamber capillary tube 1000 is connected with outer pipe C, the other end of refrigerator evaporator 1100 is connected with outer pipe B.

By above-mentioned vibrational power flow of the present utility model, the utility model directly can replace original direct-acting type dynamoelectric switching valve, and solve a commutation poor reliability noise difficult problem, the problems such as manufacture cost is high, are applicable to batch production.

Claims (13)

1. be with the dynamoelectric switching valve of speed reducer, comprise:

One mounting bracket, described mounting bracket inside has a receiving cavity;

One valve body parts, the Lower Half of described valve body parts is configured in described receiving cavity, and the inlet tube in described valve body parts and some outer pipes are through at the bottom of the chamber of described receiving cavity;

One is sleeved on the stator component on the first half of described valve body parts, and described stator component is fixedly connected with described mounting bracket, and the rotor part in the coil in described stator component and described valve body parts forms a stepper motor;

It is characterized in that, described valve body parts also comprises:

One valve casing, the one end open of described valve casing,

One valve component, described valve component comprises valve seat, inlet tube, some outer pipes, described valve seat is arranged on the aperture position of described valve casing, that being positioned at described valve casing at described valve seat is provided with a primary sealing area on the surface, a feed liquor via and some fluid vias is provided with in described valve seat, described feed liquor via and some fluid vias axially through whole valve seat, the outlet of wherein said feed liquor via be positioned at described valve casing that form liquid entering hole on the surface, a valve port is formed between the entrance of each fluid via and described primary sealing area, described inlet tube is connected with the entrance of described feed liquor via, and some outer pipes connect with the outlet of corresponding fluid via,

One to be configured on described valve component and to be positioned at the slide block assembly of described valve casing, described slide block assembly comprises a slide block, the side of the relatively described primary sealing area of described slide block is configured with secondary sealing area and at least one fluid groove, described secondary sealing area seals with primary sealing area and contacts, described fluid groove and described feed liquor via and the conducting respectively of some fluid vias; When in slide block rotation process, valve ports different on primary sealing area switches between described secondary sealing area and fluid groove, to open and close different valve ports;

One to be configured on described valve component and to be positioned at the rotor part of described valve casing;

One to be configured on described valve component and spring in described valve casing and between described rotor part and described slide block assembly, the first end of described spring withstands in the side of the relatively described spring of described slide block assembly, is pressed in by the secondary sealing area of described slide block on the primary sealing area of described valve seat;

One is configured in described valve component and is positioned at the speed reducer on described valve casing, and described rotor part drives described slide block assembly underdrive by this speed reducer.

2. the dynamoelectric switching valve of band speed reducer as claimed in claim 1, it is characterized in that, described valve component also comprises a major axis and a minor axis, the first end of described major axis is arranged on the center that described valve seat is positioned at that surface of described valve casing, and the first end of described minor axis is arranged on described valve seat and is positioned at avris appropriate location outside the primary sealing area on that surface of described valve casing; Described major axis and minor axis parallel are arranged; Described slide block assembly, spring, rotor part are sleeved on described major axis, and described speed reducer is sleeved on described minor axis.

3. the dynamoelectric switching valve of band speed reducer as claimed in claim 2, it is characterized in that, described valve body parts also comprises one and to be set on described major axis and to be positioned at the slipper bearing of described valve casing, and the side of the relatively described slide block assembly of described slipper bearing contacts with the side of opposing slider bearing in described slide block assembly; The first end of described spring withstands in the side of the relatively described spring of described slipper bearing, and is pressed on the primary sealing area of described valve seat by the secondary sealing area of described slide block by described slipper bearing.

4. the dynamoelectric switching valve of band speed reducer as claimed in claim 3, it is characterized in that, described slide block assembly also comprises a driven gear, described driven gear is enclosed within described major axis, described slide block set is on described driven gear and between described driven gear and the primary sealing area of described valve seat, and described driven gear and described speed reducer engage each other.

5. the dynamoelectric switching valve of band speed reducer as claimed in claim 4, it is characterized in that, be provided with tooth sector, reset locking plate in the outer rim of described driven gear, run locking plate, described tooth sector and described speed reducer engage each other, described driven gear outer rim reset locking plate, run locking plate and contact with described speed reducer, to limit the rotation angle of driven gear in described slide block assembly and slide block.

6. the dynamoelectric switching valve of band speed reducer as claimed in claim 5, it is characterized in that, it is the First Transition gear and the second transition gear that coaxially arrange that described speed reducer comprises, described First Transition gear and described rotor part engage each other, and the tooth sector in described second transition gear and described slide block assembly engages each other.

7. the dynamoelectric switching valve of band speed reducer as claimed in claim 6, it is characterized in that, described valve body parts also comprises one and to be arranged on described minor axis second end and to be positioned at the spring sheet of described valve casing, described spring sheet contacts with the side of the relatively described spring sheet of described speed reducer, is axially limited on described minor axis by described speed reducer.

8. the dynamoelectric switching valve of band speed reducer as claimed in claim 7, it is characterized in that, in the upper end outer rim of described rotor part, one multistage magnet ring is installed, that one end of the relatively described slide block assembly of described rotor part is configured with driving gear, and described driving gear and described First Transition gear engage each other.

9. the dynamoelectric switching valve of band speed reducer as claimed in claim 8, it is characterized in that, rotor bearing mounting hole, rotary shaft hole and spring mounting hole is coaxially arranged with in described rotor part, described major axis is successively through described spring mounting hole, rotary shaft hole and rotor bearing mounting hole, second end of described major axis is bearing in described rotor bearing mounting hole by rotor bearing, and the second end of described spring to be inserted in described spring mounting hole and to withstand on the transitional surface of described spring mounting hole and described rotary shaft hole.

10. the dynamoelectric switching valve of band speed reducer as claimed in claim 9, is characterized in that, the Ke Di center of described valve casing is provided with a groove, and the end of the second end of described major axis to be inserted in described groove and to withstand on the bottom land of described groove.

The dynamoelectric switching valve of 11. band speed reducer as claimed in claim 10, it is characterized in that, described fluid via is two, described outer pipe is also two and is separately fixed in corresponding fluid via, form the first valve port and the second valve port between two fluid vias and described primary sealing area respectively, described dynamoelectric switching valve can realize one of following four kinds of working staties:

First working state, described primary sealing area and secondary sealing area cooperatively interact and seal, and described feed liquor via and all valve ports are closed, and first and second valve port are also in closed condition each other;

Second working state, described feed liquor via is by described fluid groove and described second valve port conducting, but cooperatively interacted by described primary sealing area and secondary sealing area and seal, close between described feed liquor via and the first valve port, and first and second valve port is also in closed condition each other;

3rd working state, described feed liquor via by described fluid groove and first and second valve port conducting described, but is cooperatively interacted by described primary sealing area and secondary sealing area and seals, and first and second valve port is also in closed condition each other;

4th working state, described feed liquor via is by described fluid groove and described first valve port conducting, but cooperatively interacted by described primary sealing area and secondary sealing area and seal, close between described feed liquor via and the second valve port, and first and second valve port is also in closed condition each other.

The dynamoelectric switching valve of 12. band speed reducer as claimed in claim 11, it is characterized in that, described first working state, the second working state, the 3rd working state, the 4th working state are arranged or discontinuous setting continuously, but described first working state is corresponding with the initial position of described stepper motor.

13. refrigerator systems, comprise refrigeration plant, described refrigeration plant comprises compressor, device for drying and filtering, condenser, dynamoelectric switching valve, cold storage room capillary tube, refrigerator evaporator, refrigerating chamber capillary tube and freezer evaporator, wherein said dynamoelectric switching valve is the dynamoelectric switching valve of the band speed reducer of any one of claim 1 to 12 claim, outer pipe in the dynamoelectric switching valve of described band speed reducer is two, be the first outer pipe and the second outer pipe, wherein, inlet tube in the dynamoelectric switching valve of described band speed reducer is connected with one end of described device for drying and filtering, the other end of described device for drying and filtering is connected with one end of described condenser, the other end of described condenser is connected by compressor one end with described freezer evaporator, the other end of described freezer evaporator is connected with one end of described refrigerating chamber capillary tube on the one hand, be connected with one end of described refrigerator evaporator on the other hand, the other end of described refrigerating chamber capillary tube is connected with described second outer pipe, the other end of described refrigerator evaporator is connected with described first outer pipe.