KR20160058063A - 4-way refrigerant valve for refrigerator - Google Patents

Abstract

The present invention provides a four-way refrigerant valve for a refrigerator to control the flow of a refrigerant in a refrigerator. The four-way refrigerant valve includes: a driving unit; a valve plate having an inlet and first, second, and third outlets; a valve housing forming a chamber in which the refrigerant flows with the valve plate by being connected to the valve plate to be sealed; and a valve body arranged in the chamber and selectively opening and closing the first to third outlets. The valve body has: a closing unit closing at least one among the first to third outlets; and an opening unit moving the refrigerant by opening at least one among the first to third outlets.

Description

4-way REFRIGERANT VALVE FOR REFRIGERATOR for a refrigerator [0002]

The present invention relates to a four-way refrigerant valve installed in a refrigerant passage of a refrigerator and controlling the flow of the refrigerant.

Prior art refrigerator refrigerant control four-way refrigerant valves having one inlet and three outlets generally operate in a mode of opening and closing only one outlet of the three outlets. Accordingly, such a conventional four-way refrigerant valve has a limitation in use, and from this, a differential pressure action related to energy saving can not be expected.

It is known in the art to add a two-way refrigerant valve to the refrigerant flow path to address this problem. However, adding the two-way refrigerant valve complicates the structure of the refrigerant flow path and raises the manufacturing cost. Further, since the four-way refrigerant valve and the two-way refrigerant valve are used, energy saving can not be achieved.

As an example of a conventional four-way refrigerant valve, Korean Patent Laid-Open Publication No. 2004-0084784 proposes a four-way refrigerant valve having an operating mode in which both outlets are closed by using two valve bodies. However, the use of two valve bodies complicates the internal structure of the valve, increases the valve volume and manufacturing cost, and does not achieve energy saving

Korean Patent Publication No. 2004-0084784

Disclosure of Invention Technical Problem [8] The present invention has been made in order to solve the problems of the prior art described above, and provides a four-way refrigerant valve having a plurality of refrigerant channels switched using one valve body and having improved maneuverability due to a small-

The four-way refrigerant valve according to the exemplary embodiment of the present invention includes a driving unit, a valve plate having an inlet and first to third outlets, and a chamber sealed and connected to the valve plate, And a valve body disposed in the chamber and rotated by the driving unit to open and close the first to third outlets. The valve body includes an opening for closing at least one of the first to third outlets and an opening for opening at least one of the first to third outlets to allow the refrigerant to flow.

In one embodiment, the centers of the first to third outlets are located in a fan shape centered on the rotational center of the valve body and having a central angle of 300 degrees or less. In addition, the center of each of the first to third outlets may be located on the circumference of a circle centered on the rotational center of the valve body. The center of the first to third outlets may be equally spaced from the center of rotation of the valve body.

In one embodiment, the occlusion portion has an occluding surface for occluding the first to third outlets. And the occluding surface has a fan shape centering at least about the rotational center of the valve element.

In one embodiment, the center of rotation of the valve body is located within the occluding portion, and the occluding portion and the opening are formed to be circular in the valve body.

In one embodiment, the occlusion portion has an arcuate first edge and a second edge extending between both ends of the first edge, and the second edge may have a linear or wavy shape.

In one embodiment, the driving unit rotates the valve body in the forward and reverse directions so that the valve body is located at the first switching position, the second switching position, the third switching position, and the fourth switching position. In the first switching position, both the first to third outlets are closed by the occluding portion. In the second, third and fourth switching positions, the opening is located at any one of the first to third outlets, and the remaining two are closed by the occluding portion.

In one embodiment, the occlusion portion has a concave groove extending from the outer periphery of the occluding portion toward the rotational center of the valve body in the radial direction of the rotational center of the valve body. And the concave groove is formed in the occluding portion so as to be located in any one of the first to third outlets. The opening portion includes a first opening portion facing the blocking portion in the valve body and a second opening portion located in the concave groove.

In this embodiment, the occluding portion includes a first occluding portion and a second occluding portion which are separated by the concave grooves. The first closing portion may have a fan shape having at least a center of rotation of the valve body and a central angle of 90 degrees or more and 180 degrees or less, and the second closing portion may include at least a center of rotation of the valve body, Has a fan shape of less than 90 degrees.

Further, in this embodiment, it is preferable that the valve body has a first switching position, a second switching position, a third switching position, a fourth switching position, a first intermediate switching position between the first and second switching positions, And the third intermediate switching position between the third switching position and the third switching position, and the driving unit rotates the valve body in the forward and reverse directions so as to be located at the third intermediate switching position between the third switching position and the second intermediate switching position. In the first switching position, both the first to third outlets are closed by the occluding portion. In the second, third and fourth switching positions, the first opening is located in one of the first to third outlets, and the other two are closed by the closing portion. Wherein the first opening portion is located at one of the first to third outlets and the second opening portion is located at another one of the first to third outlets at the first, second and third intermediate switching positions, The blocking portion closes the other one of the first to third outlets.

In one embodiment, the four-way refrigerant valve has a valve body spring biasing the valve body toward the valve plate. The valve body spring has a plurality of positioning legs that elastically contact the inner surface of the valve housing.

According to the four-way refrigerant valve according to the embodiment, the center of each of the first to third outlets is arranged in a fan shape having a central angle of 300 degrees or less around the center of rotation of the valve element, Improves maneuverability.

The closing portion and the opening portion of the valve body block both the first to third outlet portions of the valve plate at the respective switching positions of the valve body, or open one of them and block the other. Therefore, the four-way refrigerant valve can supply the high-temperature, high-pressure refrigerant from the compressor to each storage chamber of the refrigerator. In addition, since the closing portion of the valve body can close both of the first to third outlets at the first switching position, the pressure of the compressor can be maintained when the compressor is off, and the compressor startup time It is possible to reduce pressure to reduce energy. Further, since the closed portion of the valve element closes all of the first to third outlets, the differential pressure effect is maximized. In addition, the closed portion of the valve body has a concave groove for opening two outlets of the first to third outlets and for blocking one outflow, so that more various switching of the refrigerant passage can be realized.

Further, since the four-way refrigerant valve of the embodiment has one valve body, it is possible to realize a compact and simple structure, easy switching to various modes, and reduction in manufacturing cost.

1 is a perspective view of a four-way refrigerant valve according to one embodiment.
FIG. 2 is a perspective view of a four-way refrigerant valve according to an embodiment showing the inside of a valve housing by cutting a valve housing. FIG.
FIG. 3 is an exploded perspective view of a four-way refrigerant valve according to one embodiment illustrating components located within a valve housing, valve plate, and valve housing.
4 is a bottom perspective view showing the valve body rotating mechanism and the valve plate.
5 is a bottom view showing a valve body of a four-way refrigerant valve according to an embodiment.
6 is a bottom view showing a part of a valve plate of a four-way refrigerant valve according to an embodiment.
7 is a bottom view showing that the valve body of the four-way refrigerant valve according to the embodiment is located at the origin position.
8 is a bottom view showing that the valve body of the four-way refrigerant valve according to the embodiment is in the first switching position.
9 is a bottom view showing that the valve body of the four-way refrigerant valve according to the embodiment is in the second switching position.
10 is a bottom view showing that the valve body of the four-way refrigerant valve according to the embodiment is in the third switching position.
11 is a bottom view showing that the valve body of the four-way refrigerant valve according to the embodiment is in the fourth switching position.
12 is a bottom view showing a valve body of a four-way refrigerant valve according to yet another embodiment.
13 is a bottom view showing that the valve body of the four-way refrigerant valve according to another embodiment is located at the origin position.
14 is a bottom view showing that the valve body of the four-way refrigerant valve according to another embodiment is in the first switching position.
15 is a bottom view showing that the valve body of the four-way refrigerant valve according to another embodiment is in the first intermediate switching position.
16 is a bottom view showing that the valve body of the four-way refrigerant valve according to another embodiment is in the second switching position.
17 is a bottom view showing that the valve body of the four-way refrigerant valve according to another embodiment is in the second intermediate switching position.
18 is a bottom view showing that the valve body of the four-way refrigerant valve according to another embodiment is in the third switching position.
19 is a bottom view showing that the valve body of the four-way refrigerant valve according to another embodiment is in the third intermediate switching position.
20 is a bottom view showing that the valve body of the four-way refrigerant valve according to another embodiment is in the fourth switching position.

An embodiment of a four-way refrigerant valve will be described with reference to the accompanying drawings. In the accompanying drawings, like reference numerals designate like or corresponding components or parts.

1 to 11, a four-way refrigerant valve 100 according to an embodiment includes a driving unit 110 for rotating the valve body 140 step by step, a first inlet 121, A valve housing 120 having an outlet 122A, 122B and 122C; a valve housing 131 sealingly connected to the valve plate 120 to form a chamber VC, And a valve body 140 that is disposed in the first chamber 110 and is rotated by the driving unit 110 and selectively opens and closes the first to third outlets 122A, 122B, and 122C. Accordingly, the four-way refrigerant valve 100 can control three refrigerant flow paths through which the refrigerant flows from the inlet 121 to the first to third outlets 122A, 122B and 122C, The three refrigerant passages are switched solely or in combination by the opening and closing operation.

1 to 3, the driving unit 110 includes a stator 111 and a rotor 112 as a power source for driving. The stator 111 has a donut shape and includes a wound coil. The stator 111 generates a magnetic force by power supply. In the four-way refrigerant valve 100 of one embodiment, the stator 111 is disposed inside the stator housing 132. A stator housing 132 holding the stator 111 is removably engaged with the bracket 133 and is positioned to surround the valve housing 131. The bracket 133 is engaged with the valve plate 120 at its opening 134. The bracket 133 has a pair of opposing hook fixing hook fingers 135 and the stator housing 132 is fixed to the bracket 133 by the engagement between the hook finger 135 and the outer surface of the stator housing 132 So that the stator 111 is positioned to surround the rotor 112. The valve housing 131 includes a cylindrical large diameter portion 131LD that substantially covers the valve plate 120 and a cylindrical large diameter portion 131LD extending coaxially from the large diameter portion 131LD and having a diameter smaller than the diameter of the large diameter portion 131LD. And a small diameter portion 131SD. The rotor 112 includes a cylindrical body having a bore vertically opened, and includes a magnet. The rotor 112 is disposed inside the small diameter portion 131SD of the valve housing 131. The rotor 112 rotates forward and backward in a stepwise manner by the magnetic force generated by the stator 111.

The driving unit 110 includes a valve body rotating mechanism for rotating the valve body 140 by receiving a rotational force generated by the stator 111 and the rotor 112. In this embodiment, the valve body rotating mechanism includes a driving gear 113 detachably coupled to the lower end of the rotor 112 and rotating together with the rotor 112, And a driven gear 114 rotated by the rotation of the driven gear 113. The driving gear 113 includes a cylindrical body having a bore 113BR in which a rotor rotation shaft 124 is inserted in the longitudinal direction and a gear tooth 113GT at the lower end and a plurality of fittings And a groove 113FG. The rotor 112 has a component (not shown) that is fitted in the gap between the fitting grooves 113FG at the lower end thereof and performs detachable coupling between the rotor 112 and the driving gear 113. The rotor 112 is supported by the drive gear 113 with respect to the valve plate 120. The driven gear 114 has a gear tooth 114GT which meshes with the gear tooth 113GT of the drive gear 113 around the driven gear 114. [ The driven gear 114 is provided with a pair of stoppers 114ST protruding from the outer periphery of the upper end thereof more than the gear teeth 114GT and the stopper 114ST can contact the middle cylindrical portion of the drive gear 113 Do. When the stopper 114ST of the driven gear 114 contacts the cylindrical portion of the drive gear 113 during the rotation of the driven gear 114 by the rotation of the rotor 112, 140 is stopped.

2 and 3, the four-way refrigerant valve 100 includes a valve body spring 150 disposed in the valve housing 131 and biasing the valve body 140 with the valve plate 120, 112 to the driving gear 113 side. The valve body spring 150 is disposed between the stepped portion 113SP of the drive gear 113 and the upper surface of the valve plate 120. [ The rotor spring 160 is disposed between the upper inner surface of the valve housing 131 and the upper end of the rotor 112. The valve body spring 150 can be biased toward the valve plate 120 by the elastic force of the rotor spring 160.

The valve body spring 150 has a disk portion 151 and two support legs 152 bent downward from the outer periphery of the disk portion 151 and three positions bending downward between the support legs 152 And a setting leg 153. The support leg 152 and the positioning leg 153 are located outside the drive gear 113 and the driven gear 114. The support leg 152 is in contact with the upper surface of the valve plate 120. The length of the positioning leg 153 is shorter than the length of the support leg 152 and has a protrusion 154 protruding outward on the outer surface. The position setting leg 153 is bent with respect to the disk portion 151 such that the lower end of the position setting leg 153 is positioned further outward than the lower end of the support leg 162. For example, 131LD). The valve body spring 150 is positioned within the large diameter portion 131LD by the elastic force applied by the positioning leg 153 to the inner surface of the large diameter portion 131LD of the valve housing 131, Is not easily separated from the large diameter portion 131LD due to the elastic force applied to the large diameter portion 131LD through the projection 154. [

The through hole 155 through which the rotor rotation shaft 124 of the valve plate 120 passes and the valve body rotation shaft 125 of the valve plate 120 are fitted to the disk portion 151 of the valve body spring 150 A through hole 156 is formed. The valve body spring 150 has a spring for urging the driven gear 114 and the valve body 140 downward to elastically press the valve body 140 against the valve plate 120. In this embodiment, as the spring, the valve body spring 150 is provided with a leaf spring 157 extending in an arc shape from the disk portion 151. The leaf spring 157 is formed on the disc portion 151 in the form of a cantilever. The leaf spring 157 is slightly bent with respect to the disk portion 151 so that its tip end is located lower than the disk portion 161. [ The through hole 156 through which the valve body rotating shaft 125 is inserted is pierced at the tip of the leaf spring 157.

The valve body spring 150 has a holder arm 158 protruding in an arc shape from the disk 151 on the outside of the leaf spring 157. The holder arm 158 can be fitted in the groove 114HG formed in the circumferential direction at the upper end of the driven gear 114. [ For example, when the valve housing 131 is assembled to the valve plate 120, the holder arm 158 is fitted in the groove 114HG of the driven gear 114 to separate the valve body 140 from the valve plate 120 The assembling operation can be performed.

The rotor spring 160 has three upwardly bent elastic legs 161 and a through hole 162 through which the rotor rotation axis 124 of the valve plate 120 is inserted is formed at the center thereof. The rotor spring 160 is slightly deformed so that the resilient leg 161 applies a spring force to the rotor 112 and is disposed between the rotor 112 and the upper inner surface of the valve housing 131. [ The rotor 112 is biased toward the valve body spring 150 by the rotor spring 160.

The valve plate 120 having the inlet 121 into which the refrigerant flows into the chamber VC and the first through third outlets 122A, 122B and 122C through which the refrigerant flows out of the chamber VC, . The inlet 121 and the first, second, and third outlets 122A, 122B, and 122C are formed through the disc portion 126. The rotor rotation axis 124 passing through the rotor 112 and the drive gear 113 extends upward from the center of the upper surface of the disk portion 126. A circular valve seat 123 is provided on the upper surface of the disc portion 126 so as to be in surface contact with the closed portion 142 of the valve body 140. The first to third outlets 122A, 122B and 122C are formed in the disc portion 126 through the valve seat 123. [ A valve body rotating shaft 125 passing through the driven gear 114 extends upward from the center of the upper surface of the valve seat 123. The inlet 121 is located on the opposite side of the valve seat 123 with respect to the rotor rotational shaft 124.

Referring to FIG. 4, an inlet pipe mount 127 for connection with an inlet pipe IP (see FIG. 1) is provided on the lower surface of the valve plate 120 in correspondence with the inlet port 121. The bottom surface of the valve plate 120 is provided with fitting holes 128A, 128B and 128C corresponding to the first to third outlets 122A, 122B and 122C, respectively, and an outflow pipe OP (see Fig. 1) And an outlet pipe mount 128 for connection with the outlet pipe. The first to third outlets 122A, 122B and 122C are opened at the respective fitting holes 128A, 128B and 128C. The outflow pipes IP are respectively fitted to the fitting holes 128A, 128B and 128C.

The valve housing 131 is sealingly engaged with the disc portion 126 of the valve plate 120. That is, the outer periphery of the large diameter portion 131LD of the valve housing 131 and the outer periphery of the disk portion 126 of the valve plate 120 are welded to each other to weld the valve housing 131 and the valve plate 120 Thereby forming a chamber VC through which the refrigerant flows. The small diameter portion 131SD of the valve housing 131 is inserted into the cylindrical space of the stator 111. [

The valve body (140) is engaged with the driven gear (114). The valve body 140 is rotated relative to the valve plate 120 by the rotation of the rotor 112 and the drive gear 113 and the driven gear 114 so that the first to third outlets 122A, 122C. The valve body 140 may be integrally formed with the driven gear 114 or may be separately provided and coupled to the driven gear 114. The valve body 140 can be rotated in the clockwise direction and counterclockwise direction by the forward and reverse rotation of the rotor 112.

4 and 5, the valve body 140 includes a disc portion 141, an occluding portion 142, and an opening portion 143. As shown in FIG. The valve body 140 can be formed by injection using a plastic material having good abrasion resistance. The occluding portion 142 closes one or more of the first to third outlets 122A, 122B, and 122C. The closing portion 142 is formed in a pad shape slightly protruding downward from the disk portion 141. The opening 143 opens one of the first to third outlets 122A, 122B, and 122C. The opening portion 143 is a space obtained by subtracting the space of the closing portion 142 from the disk portion 141 in the disk-shaped space having the thickness equal to the height of the opening portion 142 projecting from the disk portion 141. Therefore, in accordance with the shape of the disk portion 141, the closing portion 142 and the opening portion 143 form a circular disk shape in the valve body 140. [ In addition, in the valve body 140, the opening portion 143 faces the closing portion 142. When the occluding portion 142 closes one or more of the first to third outlets 122A, 122B, and 122C, the remaining outlet communicates with the chamber VC through the opening 143, . A through hole 145 through which the valve body rotational shaft 125 of the valve plate 120 is inserted through the disc portion 141 and the blocking portion 142 is formed. The rotation center RC of the valve body 140 becomes the center of the through hole 145 or the valve body rotation axis 125 and is located in the closed portion 142. [

3 to 6, when the valve plate 120 is viewed from above or below, the centers 122AC, 122BC and 122CC of the first to third outlets 122A, 122B and 122C are connected to the valve body 140, The first to third outlets 122A, 122B and 122C are formed in the valve plate 120 so as to be located in the sector FS centered on the center of rotation RC of the valve plate 120. [ In this case, the central angle CA1 of the sector FS may be, for example, 300 degrees or less, preferably 180 degrees or less. In this embodiment, as shown in Fig. 6, the center angle of the sector FS is about 180 degrees. The centers 122AC, 122BC and 122CC of the first to third outlets 122A, 122B and 122C are connected to the rotation center RC of the valve body 140 more than the outer periphery of the disk portion 141 of the valve body 140, . The centers 122AC, 122BC and 122CC of the first to third outlets 122A, 122B and 122C are connected to the center of the fitting holes 128A, 128B and 128C of the outlet tube mount 128, And is arranged close to the rotation center RC. That is, the centers 122AC, 122BC, and 122CC of the outlets 122A, 122B, and 122C and the centers of the fitting holes 128A, 128B, and 128C are not concentric. The centers 122AC, 122BC and 122CC of the first to third outlets 122A, 122B and 122C are connected to the circumference of one virtual circle (IC) centered on the rotation center RC of the valve body 140 . The centers 122AC, 122BC and 122CC of the first to third outlets 122A, 122B and 122C can be equally spaced from each other with respect to the rotation center RC of the valve body 140. [ In this embodiment, the centers 122AC, 122BC, and 122CC of the first to third outlets 122A, 122B, and 122C are spaced at an equal angle of, for example, 90 degrees with respect to the rotation center RC of the valve body 140 . That is, the central angle with respect to the center of rotation RC between any one of the centers of the first to third outlets 122A, 122B, and 122C and the other one is half the central angle CA1 of the sector FS described above.

4 and 5, the closed portion 142 for closing the first to third outlets 122A, 122B and 122C protrudes from the lower surface of the disk portion 141 with a substantially uniform thickness, Becomes the closed surface 142S, and the occluding surface 141S comes into surface contact with the valve seat 123. For example, when the valve body 140 is viewed from below, the closed surface 142S of the closed portion 142 is formed in a fan shape having a central angle of about 300 degrees or less with respect to the rotation center RC of the valve body 140, And may preferably have a shape capable of covering all of the first to third outlets 122A, 122B, and 122C. That is, the occluding surface 142S of the occluding portion 142 has a shape slightly larger than approximately a half circle when viewed from below the valve body 140. In this embodiment, the occluding portion 142 has a second edge 142WE of a corrugated shape extending between the arc-shaped first edge 142CE and both ends of the first edge 142CE. As another example, the second edge 142WE may have a linear shape. The arc-shaped edge 142CE corresponds to the circular arc of the sector FS about the center of rotation RC of the valve body 140 described above. Due to the second edge 142WE of the corrugation, the occluding portion 142 has a pair of recesses 142CP at the second edge 142WE. The concave portion 142CP is located closer to the rotation center RC of the valve body 140 than the edge of the valve body 140. [ When the valve body 140 rotates, the recess 142CP can be positioned adjacent to the first to third outlets 122A, 122B, and 122C. The opening 143 is provided with a protrusion 144 which protrudes less than the occluding surface 142S. The protrusion 144 is for coupling with the driven gear 114.

In the four-way refrigerant valve 100 of the embodiment, the valve body 140 rotates relative to the valve plate 120, so that the closing portion 142 and the opening portion 143 of the valve body 140 are in contact with the first, And selectively opens and closes the third outlets 122A, 122B, and 122C. The rotation of the valve body 140 is performed by the rotation of the rotor 112, the drive gear 113 and the driven gear 114 that rotate by the magnetic force of the stator 111. [ Pulse-shaped power is applied to the stator 111. The pps shown below is an acronym for Pulse Per Second, which means the number of pulses per second, and the pulse refers to a short-time electrical flow. The driven gear 114 meshing with the driving gear 113 rotating together with the rotor 112 is also applied to the stator 111 and the stator 111. Thus, And is intermittently rotated in accordance with the number of pulses per second of the pulse-like power applied to the coil 111.

The four-way refrigerant valve 100 of one embodiment is configured to rotate relative to the valve plate 120 of the valve body 140 (rotation in the clockwise direction CW and the counterclockwise direction CCW about the rotation center RC) Way refrigerant valve 100. The refrigerant flow path of the refrigerant passing through the four-way refrigerant valve 100 is switched. For example, the valve body 140 of the four-way refrigerant valve 100 of the embodiment performs a switching operation between the first to fourth switching positions to switch the flow path of the refrigerant.

The first switching position is a position of the valve body 140 shown in Fig. 8 where the closing portion 142 of the valve body 140 is connected to the first outlet 122A of the valve plate 120, Both the second outlet 122B and the third outlet 122C are closed. Therefore, in the first switching position, the refrigerant does not flow from the outlet 121 to the first to third outlets 122A, 122B, and 122C. The second switching position is the position of the valve body 140 shown in Fig. 9, and the valve body 140 is rotated counterclockwise from the first switching position. In the second switching position, the first outlet 122A is communicated with the inlet 121 of the valve plate 120 by the opening 143 of the valve body 140, and the second outlet 122B and the third outlet (122C) is closed by the closure part (142). Therefore, in the second switching position, the refrigerant flows from the inlet 121 to the first outlet 122A. The third switching position is the position of the valve body 140 shown in Fig. 10, and the valve body 140 is further rotated counterclockwise from the second switching position. In the third switching position, the second outlet 122B is communicated with the inlet 121 by the opening 143 of the valve body 140, and the first outlet 122A and the third outlet 122C are closed As shown in Fig. Therefore, in the third switching position, the refrigerant flows from the inlet 121 to the second outlet 122B. The fourth switching position is the position of the valve body 140 shown in Fig. 11, and the valve body 140 is rotated counterclockwise from the third switching position. In the fourth switching position, the third outlet 122C is communicated with the inlet 121 by the opening 143, and the first outlet 122A and the second outlet 122B are closed by the closing portion 142, do. Therefore, in the fourth switching position, the refrigerant flows from the inlet 121 to the third outlet 122C.

Referring again to Figs. 7 to 11, an operation example of the four-way refrigerant valve 100 of the embodiment will be described.

Referring to FIG. 7, no electric power is supplied to the stator 111, that is, 0 pps, and the valve body 140 is in the home position. Referring to FIG. 8, electric power of 4 pps is supplied to the stator 111, and the valve body 140 is slightly rotated counterclockwise (CCW). 7, power of 4 pps is supplied to the stator 111 to slightly rotate the rotor 112, thereby preventing noise generated between the driving gear 113 and the driven gear 114. [ The first to third outlets 122A, 122B and 122C are closed by the closed portion 142 of the valve body 140 at the position of the valve body 140 shown in Figs. 7 and 8, It can not flow from the inlet 121 to the first to third outlets 122A, 122B and 122C. Therefore, the four-way refrigerant valve 100 performs a differential pressure action.

9, electric power of 64 pps is supplied to the stator 111, and the valve body 140 is rotated by an angle with respect to the rotation center RC of the outlet that is adjacent counterclockwise (CCW) 90 degrees in the example), and is located at the second switch position from the first switch position. The second outlet 122B and the third outlet 122C are closed by the closure 142 and the opening 143 of the valve body 140 is located at the first outlet 122A and the inlet The refrigerant flowing into the chamber VC flows out to the first outlet 122A.

10, electric power of 124 pps is supplied to the stator 111 so that the valve body 140 rotates by an angle with respect to the rotation center RC of the adjacent outlet in the counterclockwise direction CCW, 2 switching position in the third switching position. The first outlet 122A and the third outlet 122C are then closed by the closure 142 and the opening 143 of the valve body 140 is located at the second outlet 122B, The refrigerant flowing into the chamber VC flows out to the second outlet 122B.

11, electric power of 184 pps is supplied to the stator 111 so that the valve body 140 rotates by an angle with respect to the rotation center RC of the adjacent outlet in the counterclockwise direction CCW, 3 switching position to the fourth switching position. The first outlet 122A and the second outlet 122B are then closed by the closure 142 and the opening 144 of the valve body 140 is located at the third outlet 122C so that the inlet The refrigerant flowing into the chamber VC flows out to the third outlet 122C.

Electric power for rotating the valve body 140 in the clockwise direction CW is supplied to the stator 111 so that the valve body 140 can be positioned at any one of the first to fourth switching positions.

Fig. 12 shows a valve body of a four-way refrigerant valve according to another embodiment.

The valve body 240 shown in Fig. 12 is configured to have an additional opening as compared with the valve body 140 of the above-described embodiment. The valve body 240 of this embodiment can open one or more of the first to third outlets 122A, 122B, and 122C and close the other. Therefore, the valve body 240 of this embodiment can simultaneously flow the refrigerant through the two refrigerant channels. The closing portion 242 of the valve body 240 is similar to the closing portion 142 described above but a part of the arcuate edge 142CE is deeply inserted into the rotation center RC of the valve body 242. [ Thus, the occluding portion 242 has concave grooves 245 from the outer periphery (i.e., the first edge 142CE) of the occluding portion 242 toward the rotational center RC. The concave groove 245 extends in the radial direction of the rotation center RC. The concave groove 245 is formed in the blocking portion 242 so as to be located at any one of the first to third outlets 122A, 122B, and 122C when the valve body 240 rotates. Accordingly, the valve body 240 has an additional opening by the concave groove 245 of the blocking portion 242. [ The open portion of the valve body 240 has a first opening 243A located opposite to the blocking portion 242 and a second opening 242 located in the concave portion 245 of the blocking portion 242. In this embodiment, Section 243B. The first opening portion 243A of the valve body 240 has substantially the same shape as the opening portion 143 of the valve body 140 described above.

The closing portion 242 of the valve body 240 is composed of the first closing portion 242A and the second closing portion 242B separated by the concave groove 245. [ The first closing portion 242A has a fan shape having a center angle of at least 90 degrees and not more than 180 degrees with at least the center of rotation RC of the valve body 240 as a center. The second closing portion 242B extends from the first closing portion 242A integrally with the first closing portion 242A. The second closing portion 242B has a fan shape having a central angle of 90 degrees or less with respect to the rotation center RC of the valve body 240 at least. 12, the center of the second closing portion 242B and the center of rotation RC of the second closing portion 242B extend in the radial direction passing through the middle between the straight line L1 passing through the center in the radial direction and the concave groove 245 and the center of rotation RC The angle CA2 at the second closing portion 242B may be smaller than 90 degrees, for example, 45 degrees, and the angle between the first and second closing portions 242A, (CA3) may be an angle obtained by subtracting the angle of incidence (CA2) from 180 degrees.

The four-way refrigerant valve of this embodiment having the valve body 240 is operated by the relative rotation of the valve body 240 with respect to the valve plate 120 (clockwise and counterclockwise rotation described above) Thereby switching the refrigerant passage through the valve 100. For example, the four-way refrigerant valve of another embodiment is arranged between the first switching position, the first intermediate switching position between the first and second switching positions, the second switching position, the second and third switching positions The second intermediate switching position, the third switching position, the third intermediate switching position between the third switching position and the fourth switching position, and the fourth switching position.

The first switching position in the other embodiment is the position of the valve body 240 shown in Fig. 14, and the same as the first switching position in the above-described embodiment, the closing position of the valve body 240 Closes the first to third outlets 122A, 122B, and 122C. The first intermediate switching position is the position of the valve body 240 shown in Fig. 15, and the valve body 240 is rotated counterclockwise from the first switching position. The first outlet 122A is communicated with the inlet 121 by the first opening 243A of the valve body 240 and the third outlet 122C is communicated with the valve body 240 by the first opening 243A, And the second outlet 122B is closed by the closing portion 242. The second opening portion 243B of the valve body 242 is in communication with the inlet port 121, The second switching position of another embodiment is the position of the valve body 240 shown in Fig. 16, and the valve body 240 is rotated counterclockwise from the first intermediate switching position. In the second intermediate switching position, the first outlet 122A is opened, and the second and third outlets 122B and 122C are closed by the closing portion 242 in the same manner as the second switching position of the above- do. The second intermediate switching position is the position of the valve body 240 shown in Fig. 17, and the valve body 240 is rotated counterclockwise from the second switching position. In the second intermediate switching position, the first outlet 122A and the second outlet 122B are communicated with the inlet 121 by the first opening 243A of the valve body 240, and the third outlet 122C Is closed by the closure part 242 of the valve body 240. The third switching position of another embodiment is the position of the valve body 240 shown in Fig. 18, and the valve body 240 is rotated counterclockwise from the second intermediate switching position. In this third switching position, the second outlet 122B is opened and the first and third outlets 122A and 122C are closed by the closing portion 242, similarly to the third switching position of the above-described embodiment . The third intermediate switching position is the position of the valve body 240 shown in Fig. 19, and the valve body 240 is rotated counterclockwise from the third switching position. In the third intermediate switching position, the second outlet 122B and the third outlet 122C communicate with the inlet 121 by the first opening 243A of the valve body 240, and the first outlet 122A Is communicated with the inlet 121 by the second opening 243A of the valve body 240. [ The fourth switching position of another embodiment is the position of the valve body 240 shown in Fig. 20, and the valve body 240 is rotated counterclockwise from the third intermediate switching position. In this fourth switching position, the third outlet 122C is opened and the first and second outlets 122A and 122B are closed by the closing portion 242, similarly to the fourth switching position of the above-described embodiment .

Referring to Figs. 13 to 20 again, an operation example of the four-way refrigerant valve of another embodiment will be described.

Referring to FIG. 13, no electric power is supplied to the stator 111, that is, 0 pps, and the valve body 240 is in the home position. Referring to FIG. 14, electric power of 4 pps is supplied to the stator 111, and the valve body 240 is slightly rotated in the counterclockwise direction (CCW). The first and second outlets 122A and 122B are closed by the first closing portion 242A of the valve body 240 at the position of the valve body 240 shown in Figs. 13 and 14, The outlet 122C is closed by the second closing portion 242B of the valve body 240. [ Therefore, the refrigerant can not flow from the inlet 121 to the first to third outlets 122A, 122B, and 122C, thereby performing the differential pressure action.

15, electric power of 34 pps is supplied to the stator 111 so that the valve body 240 is rotated in the counterclockwise direction CCW by half of the angle with respect to the rotation center RC of the adjacent outlet For example, 45 degrees in this embodiment), and is located at the first intermediate switching position from the first switching position. The second outlet 122B is then closed by the first closing portion 242A and the first opening 243A of the valve body 242 and the second opening 242A of the valve body 242 are closed by the first and third outlets 122A, And the refrigerant flowing into the chamber VC through the inlet 121 flows out to the first and third outlets 122A and 122C. In the first intermediate switching position, the concave groove 245 located between the first closing portion 242A and the second closing portion 242B is located at the third outlet 122C.

16, electric power of 64 pps is supplied to the stator 111, and the valve body 240 is rotated in the counterclockwise direction CCW with respect to the rotation center RC of the adjacent outlet , And is located from the first intermediate switching position to the second switching position. The second outlet 122B and the third outlet 122C are then closed by the first closing portion 242A so that the first opening 243A of the valve body 240 is positioned at the first outlet 122A So that the refrigerant introduced through the inlet 121 flows out to the first outlet 122A.

17, electric power of 94 pps is supplied to the stator 111, and the valve body 240 is rotated in the counterclockwise direction CCW with respect to the rotation center RC of the adjacent outlet , And is located from the second switching position to the second intermediate switching position. The third outlet 122C is then closed by the first closing portion 242A and the first opening 243A of the valve body 240 is located in the first and second outlets 122A and 122B, The refrigerant flowing through the inlet 121 flows out to the first and second outlets 122A and 122B.

18, electric power of 122 pps is supplied to the stator 111, and the valve body 240 is rotated in the counterclockwise direction CCW with respect to the rotation center RC of the adjacent outlet And is positioned from the second intermediate switching position to the third switching position. The first outlet portion 122A and the third outlet portion 122C are then closed by the second closing portion 242B and the first closing portion 242A and the first opening portion 243A of the valve body 240 is closed, Is located in the second outlet 122B, and the refrigerant introduced through the inlet 121 flows out to the second outlet 122B.

19, electric power of 154 pps is supplied to the stator 111, and the valve body 240 is rotated in the counterclockwise direction CCW with respect to the rotation center RC of the adjacent outlet And is positioned from the third switching position to the third intermediate switching position. The second opening 243B of the valve body 240 is located at the first outlet 122A and the first opening 243A of the valve body 240 is connected to the second and third outlets 122B and 122C. And the refrigerant introduced through the inlet 121 flows out to the first to third outlets 122A, 122B, and 122C. In the third intermediate switching position, the concave groove 245 between the first closing portion 242A and the second closing portion 242B is located at the first outlet 122A.

20, electric power of 184 pps is supplied to the stator 111, and the valve body 240 is rotated in the counterclockwise direction CCW with respect to the rotation center RC of the adjacent outlet And is positioned from the third intermediate switching position to the fourth switching position. The first outlet portion 122A and the second outlet portion 122B are closed by the first closing portion 242A and the second closing portion 242B respectively and the first opening portion 243A of the valve body 240 is closed, Is located at the third outlet 122C and the refrigerant flowing through the inlet 121 flows out to the third outlet 122C.

Further, electric power for rotating the valve body 240 in the clockwise direction (CW) is supplied to the stator 111, and the valve body 240 is rotated by the first to fourth switching positions and the first to third intermediate switching positions As shown in FIG.

The present invention described above is not limited to the embodiments shown in the above-described embodiments and the accompanying drawings. It will be apparent to those skilled in the art that various substitutions, alterations, and changes may be made without departing from the scope of the present invention.

The present invention relates to a four-way refrigerant valve, and more particularly to a four-way refrigerant valve in which a four-way refrigerant valve is connected to a stator. And the valve body is rotatably supported by the valve body so that the valve body is rotatable about the axis of the valve body. The valve mechanism includes a valve body spring, a valve body, a spring, a leaf spring, a rotor spring, and a valve body. A valve body 242 a closing portion 242A a first closing portion 242B a second closing portion 243A a first opening 243B a second opening 245 an insertion groove RC a rotation of the valve body Center, VC: chamber, FS: fan, IC: virtual circle

Claims (12)

A driving unit,
A valve plate having an inlet and first to third outlets,
A valve housing hermetically coupled to the valve plate to form a chamber through which the refrigerant flows together with the valve plate;
And a valve body disposed in the chamber and rotated by the driving unit to open and close the first to third outlets,
Wherein the valve body has a closure part for closing at least one of the first to third outlets and an open part for opening at least one of the first to third outlets to allow the refrigerant to flow
4-way refrigerant valve. The method according to claim 1,
Wherein the center of the first to third outlets is located in a fan shape centered on the rotational center of the valve element and having a central angle of 300 degrees or less
4-way refrigerant valve. The method according to claim 1,
Wherein the center of each of the first to third outlets is located on the circumference of a circle centered on the rotational center of the valve body
4-way refrigerant valve. The method according to claim 1,
The centers of the first to third outlets are equiangularly spaced from the center of rotation of the valve element
4-way refrigerant valve. The method according to claim 1,
Wherein the blocking portion has a blocking surface for blocking the first to third outlets,
Wherein the occluding surface has a sector shape having at least a center of rotation of the valve element
4-way refrigerant valve. 6. The method of claim 5,
Wherein a center of rotation of the valve body is located within the closed portion, and the closed portion and the open portion are formed to have a circular shape in the valve body
4-way refrigerant valve. 6. The method of claim 5,
Wherein the occlusion portion has an arcuate first edge and a second edge extending between both ends of the first edge, the second edge having a linear or wavy
4-way refrigerant valve. The method according to claim 1,
The valve body is rotated in the forward and reverse directions by the driving unit such that the valve body is located at the first switching position, the second switching position, the third switching position and the fourth switching position,
In the first switching position, both the first to third outlets are closed by the occluding portion,
In the second, third and fourth switching positions, the opening is located in any one of the first to third outlets, and the remaining two are closed by the closing portion
4-way refrigerant valve. The method according to claim 1,
Wherein the blocking portion has a concave groove extending in the radial direction of the rotational center of the valve body from the outer periphery of the occluding portion toward the rotational center of the valve body,
Wherein said concave groove is formed in said occluding portion so as to be located in any one of said first to third outlets,
Wherein the opening portion includes a first opening portion facing the blocking portion in the valve body and a second opening portion located in the concave groove
4-way refrigerant valve. 10. The method of claim 9,
Wherein the occluding portion includes a first occluding portion and a second occluding portion that are separated by the concave groove,
Wherein the first closing portion has a fan shape having a central angle of 90 degrees or more and 180 degrees or less with respect to at least the center of rotation of the valve element, and the second closing portion has at least a center of rotation of the valve element, Fan-shaped
4-way refrigerant valve. 10. The method of claim 9,
Wherein the valve body has a first switching position, a second switching position, a third switching position, a fourth switching position, a first intermediate switching position between the first and second switching positions, and a second switching position between the second and third switching positions. The valve body is rotated in the forward and reverse directions by the driving portion so as to be located at the second intermediate switching position between the second intermediate switching position and the third and fourth switching positions,
In the first switching position, both the first to third outlets are closed by the occluding portion,
Wherein in the second, third and fourth switching positions, the first opening is located in any one of the first to third outlets and the remaining two are closed by the closing portion,
Wherein the first opening portion is located at one of the first to third outlets and the second opening portion is located at another one of the first to third outlets at the first, second and third intermediate switching positions, And the blocking portion closes the other one of the first to third outlets
4-way refrigerant valve. The method according to claim 1,
Further comprising a valve body spring biasing the valve body toward the valve plate,
Wherein the valve body spring has a plurality of positioning legs that elastically contact the inner surface of the valve housing
4-way refrigerant valve.

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