JP2021162059A - Rotary valve type three-way valve - Google Patents

Abstract

To provide a rotary valve type three-way valve capable of suppressing fluid leakage and power loss and exhibiting high durability with a simple structure.SOLUTION: A rotary valve type three-way valve has a structure in which a high pressure side three-way valve (50) and a low pressure side three-way valve (60) are stacked at least. A first port group (51, 52, 53) of the high pressure side three-way valve (50) and a second port group (61, 62, 63) of the low pressure side three-way valve (60) are provided in a same valve box (70). First flow passages (54, 55) which selectively communicate a high pressure side port (51) with one of high pressure side inlet/outlet ports (52, 53) and second flow passages (64, 65) which selectively communicate a low pressure side port (61) with one of low pressure side inlet/outlet ports (62, 63) are formed in a same valve element (71).SELECTED DRAWING: Figure 2

Description

The present disclosure relates to a rotary valve type three-way valve.

Conventionally, a magnetic refrigerating device for producing cold heat and hot heat by utilizing the magnetic heat quantity effect is known. In the magnetic refrigeration system, it is necessary to control the flow path of the heat exchange medium (fluid) that exchanges heat with the magnetic working substance. Patent Document 1 discloses that a rotary valve is used for controlling the flow path of such a fluid.

Japanese Unexamined Patent Publication No. 2013-257104

In the fluid flow path control disclosed in Patent Document 1, eight rotary valves are used, so that the structure becomes complicated. On the other hand, a structure has been proposed in which the flow path of the fluid in the magnetic refrigerating apparatus is switched by using two three-way valves, a high-pressure side three-way valve and a low-pressure side three-way valve.

However, when the high-pressure side three-way valve and the low-pressure side three-way valve are connected in multiple stages, it is necessary to increase the degree of adhesion between the valve box and the valve body in order to prevent fluid leakage at each stage. If the degree of adhesion between the valve box and the valve body is increased, there arises a problem that friction increases, durability decreases, and power loss increases.

An object of the present disclosure is to provide a rotary valve type three-way valve having a simple structure, capable of suppressing fluid leakage and power loss, and having high durability.

A first aspect of the present disclosure is a valve box (70) having a plurality of ports (51,52,53,61,62,63) for fluids to enter and exit, and a valve box (70) arranged and driven in the valve box (70). A valve body having a flow path (54,55,64,65) that selectively communicates between the plurality of ports (51,52,53,61,62,63) according to the rotation position around the shaft (75). It is a rotary valve type three-way valve that is equipped with (71) and is used in the magnetic refrigeration system (10). The rotary valve type three-way valve has a structure in which a high-pressure side three-way valve (50) and a low-pressure side three-way valve (60) are at least laminated. The high-pressure side three-way valve (50) is a first port group (51, 53) composed of a high-pressure side port (51) and two high-pressure side inlet / outlet ports (52,53) that selectively communicate with the high-pressure side port (51). It has at least one 52,53). The low pressure side three-way valve (60) is a second port group (61, 63) composed of a low pressure side port (61) and two low pressure side inlet / outlet ports (62,63) that selectively communicate with the low pressure side port (61). It has at least one 62,63). The first port group (51,52,53) and the second port group (61,62,63) are provided in the same valve box (70). The high-pressure side three-way valve (50) is a first flow path (54,55) that selectively communicates the high-pressure side port (51) with any one of the two high-pressure side inlet / outlet ports (52,53). At least one in the circumferential direction of the drive shaft (75). The low pressure side three-way valve (60) is a second flow path (64, 65) that selectively communicates the low pressure side port (61) with any one of the two low pressure side inlet / outlet ports (62,63). At least one in the circumferential direction of the drive shaft (75). The first flow path (54,55) and the second flow path (64,65) are formed in the same valve body (71).

In the first aspect, the first flow path (54,55) of the high-pressure side three-way valve (50) and the second flow path (64,65) of the low-pressure side three-way valve (60) are the same valve body ( It is formed in the circumferential direction of 71). Therefore, even if the degree of adhesion between the valve box (70) and the valve body (71) is not increased, the pressure difference between the high-pressure side three-way valve (50) and the low-pressure side three-way valve (60) causes the circumferential direction. Fluid leakage can be suppressed. Therefore, it is possible to provide a rotary valve type three-way valve which can suppress fluid leakage and power loss with a simple structure and has high durability.

A second aspect of the present disclosure is that in the first aspect, the first port group (51,52,53) is located between the two high pressure side inlet / outlet ports (52,53). 51) is arranged in the circumferential direction of the drive shaft (75), and the second port group (61,62,63) is located between the two low-voltage side inlet / outlet ports (62,63). The first port group (51,52,53) and the second port group (61,62,63) are arranged in the circumferential direction of the drive shaft (75) so that the low pressure side port (61) is located. Each of n (n: natural number) is provided in the valve box (70) in the circumferential direction of the drive shaft (75), and the high-pressure side three-way valve (50) is provided in two adjacent first flow paths (1). The valve body (71) has n first flow path groups (54,55) including 54,55) in the circumferential direction of the drive shaft (75), and the low-pressure side three-way valve (60). ) Refers to the second flow path group (64, 65), which is a set of two adjacent second flow paths (64, 65), in the circumferential direction of the drive shaft (75) in the valve body (71). It is a rotary valve type three-way valve characterized by having n pieces in a.

In the second aspect, the flow path can be switched 2n times while the valve body (71) makes one rotation.

A third aspect of the present disclosure is, in the second aspect, the high pressure side port (51) of the first port group (51,52,53) and the second port group (61,62, 53). Each of the low-pressure side ports (61) of 63) is arranged at an angle approximately 180 ° / n different in the circumferential direction of the drive shaft (75), and the first flow of the high-pressure side three-way valve (50). The positions of the road group (54,55) and the second flow path group (64,65) of the low-pressure side three-way valve (60) are substantially the same in the circumferential direction when viewed from the axial direction of the drive shaft (75). The high-pressure side port (51) and the high-pressure side inlet / outlet port (52,53) of the first flow path group (54,55) of the high-pressure side three-way valve (50) are communicated with each other. Of the first flow path (54,55) and the second flow path group (64,65) of the low-pressure side three-way valve (60), the low-pressure side port (61) and the low-pressure side inlet / outlet port (62, The second flow path (64,65) that does not communicate with 63) is arranged so that the positions in the circumferential direction are substantially the same when viewed from the axial direction of the drive shaft (75), and the high-pressure side three-way valve. Of the first flow path group (54,55) of (50), the first flow path (54,55) that does not allow the high pressure side port (51) and the high pressure side inlet / outlet port (52,53) to communicate with each other. Of the second flow path group (64,65) of the low-pressure side three-way valve (60), the second flow path for communicating the low-pressure side port (61) and the low-pressure side inlet / outlet port (62,63). (64,65) is a rotary valve type three-way valve characterized in that the drive shafts (75) are arranged so that their positions in the circumferential direction are substantially the same when viewed from the axial direction.

In the third aspect, in the high-pressure side three-way valve (50), the first flow path (54,55) that communicates the high-pressure side port (51) and the high-pressure side inlet / outlet port (52,53) and the low-pressure side three-way valve ( In 60), the low pressure side port (61) and the second flow path (64,65) that do not communicate with the low pressure side inlet / outlet port (62,63) are connected outside the valve, and the high pressure side three-way valve (50) has high pressure. The first flow path (54,55) that does not allow the side port (51) and the high pressure side inlet / outlet port (52,53) to communicate with each other, and the low pressure side port (61) and the low pressure side inlet / outlet port (60) in the low pressure side three-way valve (60). By connecting the second flow path (64,65) that communicates with 62,63) outside the valve, the first flow path (54,55) and the second flow path (54,55) and the second flow path (54,55) whose positions in the circumferential direction substantially coincide with each other. 64,65) and can be equalized. Therefore, fluid leakage in the axial direction can be suppressed without using a sealing member.

In the fourth aspect of the present disclosure, in the third aspect, the valve body (71) equalizes 2n spaces between the valve body (71) and the valve box (70) in the circumferential direction. A rotary valve having 2n partitions (73) forming the first flow path group (54,55) and the second flow path group (64,65), each of which is divided into n parts. It is a type three-way valve.

In the fourth aspect, in each of the high pressure side three-way valve (50) and the low pressure side three-way valve (60), the fluid leakage in the circumferential direction can be suppressed by the partition (73).

A fifth aspect of the present disclosure is the first flow path (54,55) and the first flow path (54,55) located between the same pair of partitions (73) among the 2n partitions (73) in the fourth aspect. The second flow path (64, 65) is a rotary valve type three-way valve characterized by forming a pressure equalizing space communicating with the drive shaft (75) in the axial direction.

In a fifth aspect, an axial direction is used between the first flow path (54,55) and the second flow path (64,65) sandwiched by the same pair of partitions (73) without using a sealing member. Fluid leakage can be suppressed.

In the sixth aspect of the present disclosure, in the fourth or fifth aspect, the n first flow path groups (54,55) and the second flow path group (64,65) are the drive shafts. The drive shaft (75) is attached to the valve body (71) at a position corresponding to the first port group (51,52,53) and the second port group (61,62,63) in the axial direction of (75). It is a rotary valve type three-way valve characterized by including grooves (71a, 71b, 71c, 71d) formed along the circumferential direction of.

In the sixth aspect, the first channel group (54,55) and the second channel group (64,65) can be easily formed.

In the seventh aspect of the present disclosure, in any one of the fourth to sixth aspects, the high-voltage side inlet / outlet port (52,53) and the low-voltage side inlet / outlet port (62,63) are Arranged at substantially the same position in the circumferential direction of the drive shaft (75), the drive shaft (75) in the first port group (51,52,53) and the second port group (61,62,63). The difference in arrangement angle between the entrance / exit ports (52,53,62,63) adjacent to each other in the circumferential direction, and the partition (73) adjacent to each other in the circumferential direction of the drive shaft (75) in the 2n partitions (73). The arrangement angle difference is a rotary valve type three-way valve characterized in that they are substantially the same.

In the seventh aspect, the flow path switching control can be easily performed.

In the eighth aspect of the present disclosure, in the seventh aspect, the high-pressure side port (51) and the low-pressure side port (61) are corresponding regions between the entrance / exit ports (52,53,62,63), respectively. It is a rotary valve type three-way valve characterized in that it is arranged substantially in the center of the drive shaft (75) in the circumferential direction.

In the eighth aspect, the flow path switching control can be performed more easily.

A ninth aspect of the present disclosure is that in any one of the fourth to eighth aspects, the 2n partitions (73) have at least one vane in contact with the inner wall of the valve box (70). (91) is a rotary valve type three-way valve characterized in that it is used.

In the ninth aspect, the vanes (91) can further suppress fluid leakage in the circumferential direction in each of the high pressure side three-way valve (50) and the low pressure side three-way valve (60).

A tenth aspect of the present disclosure is that, in the ninth aspect, the vane (91) is pressed against the inner wall of the valve box (70) by a high-pressure fluid supplied from the high-pressure side port (51). It is a characteristic rotary valve type three-way valve.

In the tenth aspect, the vane (91) can be pressed against the inner wall of the valve box (70) without using a spring or the like.

An eleventh aspect of the present disclosure is characterized in that, in the tenth aspect, the valve body (71) is provided with a port (92) for supplying the high-pressure fluid at the base of the vane (91). It is a rotary valve type three-way valve.

In the eleventh aspect, the vane (91) is pressed against the inner wall of the valve box (70) by the high-pressure fluid supplied from the high-pressure side port (51) to the base of the vane (91) via the port (92). be able to.

FIG. 1 is a diagram showing a configuration of a magnetic refrigeration apparatus in which a rotary valve type three-way valve according to an embodiment is used. FIG. 2 is a vertical cross-sectional view of the rotary valve type three-way valve according to the embodiment. FIG. 3 is a cross-sectional view of line III-III in FIG. 1 (cross-sectional view of the high-pressure side three-way valve). FIG. 4 is a cross-sectional view of line IV-IV in FIG. 1 (cross-sectional view of the low-pressure side three-way valve). FIG. 5 is a diagram schematically showing a transition of a flow path switching state in the high-pressure side three-way valve shown in FIG. FIG. 6 is a diagram schematically showing a transition of a flow path switching state in the low-pressure side three-way valve shown in FIG. FIG. 7 is a diagram schematically showing a first flow mode of flow path control in the magnetic refrigeration apparatus shown in FIG. FIG. 8 is a diagram schematically showing a second flow mode of flow path control in the magnetic refrigeration apparatus shown in FIG. FIG. 9 is a diagram schematically showing a transition of a flow path switching state in the high-pressure side three-way valve of the rotary valve type multi-way switching valve according to the first modification. FIG. 10 is a diagram schematically showing a transition of a flow path switching state in the low-pressure side three-way valve of the rotary valve type multi-way switching valve according to the first modification. FIG. 11 is a vertical cross-sectional view of the rotary valve type three-way valve according to the second modification. FIG. 12 is a cross-sectional view of the line XII-XII in FIG. 11 (cross-sectional view of the high-pressure side three-way valve). FIG. 13 is a cross-sectional view of the line XIII-XIII in FIG. 11 (cross-sectional view of the low-pressure side three-way valve). FIG. 14 is a cross-sectional view showing a further improvement of the high pressure side three-way valve shown in FIG. FIG. 15 is a diagram showing other configurations of a magnetic refrigeration system in which a rotary valve type three-way valve is used. FIG. 16 is a vertical sectional view of a rotary valve type three-way valve according to a comparative example.

<< Embodiment >>
Hereinafter, embodiments of the present disclosure will be described with reference to the drawings.

The magnetic refrigerating apparatus (10) of the present embodiment adjusts the temperature of the heat medium by utilizing the magnetic calorific value effect. The magnetic refrigeration system (10) is applied to, for example, an air conditioner.

FIG. 1 shows the configuration of the magnetic refrigeration apparatus (10) of the present embodiment. As shown in FIG. 1, the magnetic refrigeration apparatus (10) includes a heat medium circuit (11) filled with a heat medium. Various fluids can be used as the heat medium, but in this embodiment, water is used. The heat medium circuit (11) has two magnetic refrigeration units (20), a pump (30), a low temperature heat exchanger (41), a high temperature heat exchanger (42), a high pressure side three-way valve (50), and a low pressure side. It is equipped with a three-way valve (60) and a control device (80) as components. Each component of the heat carrier circuit (11) is connected to each other via a pipe. As will be described later, in the present embodiment, the high pressure side three-way valve (50) and the low pressure side three-way valve (60) are integrally formed. Hereinafter, each component will be described.

<Magnetic refrigeration unit>
The magnetic refrigeration apparatus (10) is provided with two magnetic refrigeration units (20). In the following description, when it is necessary to distinguish between these magnetic refrigeration units (20), a branch number (specifically, 20-1 and 20-2) is added to the reference code to distinguish between the two.

As shown in FIG. 1, each magnetic refrigeration unit (20) includes a bed (22), a magnetic working substance (23), a first check valve (25) and a second check valve (26).

The bed (22) is a hollow container or column. A magnetic working substance (23) that exchanges heat with a heat medium (fluid) is housed in the bed (22), and a temperature control flow path for controlling the temperature of the heat medium is formed. The magnetic working substance (23) has a property of generating heat when a magnetic field is applied or when the applied magnetic field becomes strong, and absorbing heat when the magnetic field is removed or the applied magnetic field becomes weak. Examples of the material of the magnetic working substance (23) include Gd ₅ (Ge _0.5 Si _0.5 ) ₄ , La (Fe _1-x Si _x ) ₁₃ , La (Fe _1-x Co _x Si _y ) ₁₃ , and La (Fe 1-x Si y) 13. _1-x Si _x ) _{13 Hy} , Mn (As _0.9 Sb _0.1 ) and the like can be used.

The first and second ports (P1, P2) are formed at one end of the bed (22), and the third and fourth ports (P3, P4) are formed at the other end of the bed (22). These ports (P1, P2, P3, P4) supply the heat medium into the bed (22) and discharge the heat medium from the bed (22). Inside the bed (22), the magnetic working substance (23) and the heat medium exchange heat with the supply and discharge of the heat medium.

The first and second check valves (25,26) are valves with two ports that allow fluid to flow in only one direction between these ports. In the present embodiment, the first check valve (25) and the second check valve (26) have the same structure. The first check valve (25) is connected to the first port (P1) and restricts the inflow of heat medium from the first port (P1) to the bed (22). Further, the second check valve (26) is connected to the second port (P2) and restricts the outflow of the heat medium from the second port (P2).

Although not shown, the magnetic refrigeration unit (20) has a magnetic field modulator that adjusts the strength of the magnetic field applied to the magnetic working substance (23). The magnetic field modulator is composed of, for example, an electromagnet capable of modulating the magnetic field. The magnetic field modulator has a first modulation operation of applying a magnetic field to the magnetic working material (23) or strengthening the applied magnetic field, and removing or applying a magnetic field applied to the magnetic working material (23). The second modulation operation is performed to weaken.

<Heat exchanger>
The low-temperature heat exchanger (41) has an inflow end and an outflow end of the heat medium, and the heat medium cooled by the magnetic refrigeration unit (20) and a predetermined cooling target (for example, secondary refrigerant or air) are separated from each other. Let the heat exchange. The high-temperature heat exchanger (42) has an inflow end and an outflow end of the heat medium, and heats the heat medium heated by the magnetic refrigeration unit (20) and a predetermined heating target (for example, a secondary refrigerant or air). Let the heat exchange.

<pump>
The pump (30) is a device that conveys a heat medium (fluid). In this magnetic refrigeration apparatus (10), the arrangement position of the pump (30) is not particularly limited. For example, when the pump (30) is arranged on the inflow end side of the high temperature heat exchanger (42), the high temperature heat exchanger (30) is arranged. A flow of heat medium is formed from one end to the other end of 42). The type of the pump (30) is not particularly limited, but various types of pumps such as a centrifugal pump and a reciprocating piston pump can be adopted.

<Rotary valve type three-way valve>
FIG. 2 is a vertical cross-sectional view of the rotary valve type three-way valve of the present embodiment, FIG. 3 is a cross-sectional view of line III-III in FIG. 1 (cross-sectional view of the high-pressure side three-way valve), and FIG. It is sectional drawing (cross-sectional view of low-pressure side three-way valve) of line IV-IV in FIG.

The rotary valve type three-way valve of the present embodiment shown in FIGS. 2 to 4 includes a valve box (70) having a plurality of ports (51,52,53,61,62,63) for entering and exiting a heat medium (fluid). A flow path (54,) arranged in the valve box (70) and selectively communicating between a plurality of ports (51,52,53,61,62,63) according to the rotation position around the drive shaft (75). It is equipped with a valve body (71) having 55,64,65). The valve box (70) is composed of, for example, a cylindrical metal member. The valve body (71) is, for example, a cylindrical metal member, and the outer diameter of the valve body (71) is set so as to fit exactly into the cylindrical surface inside the valve box (70). The drive shaft (75) penetrates a hole in the ceiling of the valve box (70) to connect the top of the valve body (71) to a motor (not shown). A sealing member (76) for preventing fluid leakage is provided on the wall surface of the hole in the ceiling of the valve box (70). In FIG. 2, the axis of the drive shaft (75) is represented by "C".

The rotary valve type three-way valve of the present embodiment has a structure in which a high-pressure side three-way valve (50) and a low-pressure side three-way valve (60) are laminated.

The high-pressure side three-way valve (50) is a first port group (51,52) consisting of a high-pressure side port (51) and two high-pressure side inlet / outlet ports (52,53) that selectively communicate with the high-pressure side port (51). , 53). The first port group (51,52,53) is along the circumferential direction of the drive shaft (75) so that the high pressure side port (51) is located between the two high pressure side inlet / outlet ports (52,53). , Placed on the outer cylindrical surface of the valve box (70). Each port of the first port group (51,52,53) opens in the valve box (70). The high pressure side three-way valve (50) may have a plurality of first port groups (51,52,53).

The low pressure side three-way valve (60) is a second port group (61,62) consisting of a low pressure side port (61) and two low pressure side inlet / outlet ports (62,63) that selectively communicate with the low pressure side port (61). , 63). The second port group (61,62,63) is along the circumferential direction of the drive shaft (75) so that the low pressure side port (61) is located between the two low pressure side inlet / outlet ports (62,63). , Placed on the outer cylindrical surface of the valve box (70). Each port of the second port group (61,62,63) opens in the valve box (70). The low pressure side three-way valve (60) may have a plurality of second port groups (61,62,63).

In the present embodiment, the first port group (51,52,53) of the high-pressure side three-way valve (50) and the second port group (61,62,63) of the low-pressure side three-way valve (60) are the same. It is provided in the valve box (70). In addition, all ports can be closed in both the high-pressure side three-way valve (50) and the low-pressure side three-way valve (60).

Further, in the present embodiment, the high-pressure side port (51) of the first port group (51,52,53) and the low-pressure side port (61) of the second port group (61,62,63) are drive shafts. In the circumferential direction of (75), they are arranged at different angles by about 180 °. The two high-voltage side inlet / outlet ports (52,53) are arranged on both sides of the high-voltage side port (51) at an angle of approximately 90 ° from the high-voltage side port (51) in the circumferential direction of the drive shaft (75). Will be done. Similarly, the two low pressure side inlet / outlet ports (62,63) are offset from the low pressure side port (61) by approximately 90 ° on both sides of the low pressure side port (61) in the circumferential direction of the drive shaft (75). Be placed.

When n (where n is a natural number) are provided for each of the first port group (51,52,53) and the second port group (61,62,63), the high-voltage side port (51) and the low-voltage side port are provided. It is arranged at an angle approximately 180 ° / n different from that of (61). Further, the two high-voltage side inlet / outlet ports (52,53) are offset by approximately 90 ° / n from the high-voltage side port (51) in the circumferential direction of the drive shaft (75) on both sides of the high-voltage side port (51). Placed in. Similarly, the two low pressure side inlet / outlet ports (62,63) are offset by approximately 90 ° / n from the low pressure side port (61) in the circumferential direction of the drive shaft (75) on both sides of the low pressure side port (61). Arranged at an angle.

The high pressure side three-way valve (50) drives a first flow path (54,55) that selectively communicates one of the high pressure side port (51) and the two high pressure side inlet / outlet ports (52,53). It has two in the circumferential direction of the shaft (75). Hereinafter, two adjacent first flow paths (54,55) will be referred to as a first flow path group (54,55) as a set. The high pressure side three-way valve (50) may have a plurality of first flow path groups (54,55).

The low pressure side three-way valve (60) drives a second flow path (64,65) that selectively communicates one of the low pressure side port (61) and the two low pressure side inlet / outlet ports (62,63). It has two in the circumferential direction of the shaft (75). Hereinafter, two adjacent second flow paths (64,65) are referred to as a second flow path group (64,65) as a set. The low pressure side three-way valve (60) may have a plurality of second flow path groups (64,65).

In the present embodiment, the first flow path group (54,55) of the high-pressure side three-way valve (50) and the second flow path group (64,65) of the low-pressure side three-way valve (60) are the same. It is formed on the valve body (71). Further, the first flow path group (54,55) and the second flow path group (64,65) are arranged so that their positions in the circumferential direction substantially coincide with each other when viewed from the axial direction of the drive shaft (75). .. Here, as described above, the high-pressure side port (51) and the low-pressure side port (61) are approximately 180 ° in the circumferential direction of the drive shaft (75) (when n ports are provided, approximately 180 °). ° / n) Arranged at different angles. Therefore, the first flow path (54,55) that communicates the high-voltage side port (51) and the high-voltage side inlet / outlet port (52,53), and the low-voltage side port (61) and the low-voltage side inlet / outlet port (62,63). The second flow path (64,65) that does not communicate with the second flow path (64,65) is arranged so that the positions in the circumferential direction substantially coincide with each other when viewed from the axial direction of the drive shaft (75). Further, a first flow path (54,55) that does not allow the high pressure side port (51) and the high pressure side inlet / outlet port (52,53) to communicate with each other, and a low pressure side port (61) and a low pressure side inlet / outlet port (62,63). The second flow path (64, 65) communicating with the second flow path (64, 65) is arranged so that the positions in the circumferential direction substantially coincide with each other when viewed from the axial direction of the drive shaft (75).

As shown in FIGS. 3 and 4, in the valve body (71), the space between the valve body (71) and the valve box (70) is evenly divided into two in the circumferential direction, and the first flow path group It has two partitions (73) that form (54,55) and a second channel group (64,65). As will be described later, the first flow path (54,55) and the second flow path (64,65) sandwiched by the same pair of partitions (73) communicate with each other in the axial direction of the drive shaft (75). A space may be constructed.

When n (n: natural numbers) of the first flow path group (54,55) and the second flow path group (64,65) are formed, the valve body (73) is used for the valve body (73). The space between 71) and the valve box (70) is evenly divided into 2n pieces in the circumferential direction.

Further, as shown in FIGS. 2 to 4, the first flow path group (54,55) is a valve at a position corresponding to the first port group (51,52,53) in the axial direction of the drive shaft (75). The body (71) includes grooves (71a, 71b) formed along the circumferential direction of the drive shaft (75). In other words, in the high pressure side three-way valve (50), the first flow path group (54,55) is formed between the inner surface of the valve box (70) and the groove (71a, 71b). The position of the first flow path group (54,55) in the axial direction of the drive shaft (75) is the same as the position of the first port group (51,52,53) as shown in FIG. Therefore, depending on the rotation angle of the valve body (71), the groove (71a, 71b) faces any port of the first port group (51,52,53).

Similarly, the second flow path group (64,65) is attached to the valve body (71) at a position corresponding to the second port group (61,62,63) in the axial direction of the drive shaft (75). Includes grooves (71c, 71d) formed along the circumferential direction of 75). In other words, in the low pressure side three-way valve (60), a second flow path group (64,65) is formed between the inner surface of the valve box (70) and the groove (71c, 71d). The position of the second flow path group (64,65) in the axial direction of the drive shaft (75) is the same as the position of the second port group (61,62,63) as shown in FIG. Therefore, depending on the rotation angle of the valve body (71), the groove (71c, 71d) faces any port of the second port group (61,62,63).

Further, as shown in FIGS. 3 and 4, two high-pressure side inlet / outlet ports (52,53) of the high-pressure side three-way valve (50) and two low-pressure side inlet / outlet ports (62, 53) of the low-pressure side three-way valve (60). 63) is arranged at substantially the same position in the circumferential direction of the drive shaft (75). Further, in the first port group (51,52,53) and the second port group (61,62,63), the entrance / exit ports (52,53,62,63) adjacent to each other in the circumferential direction of the drive shaft (75) The arrangement angle difference (pitch angle) and the arrangement angle difference (pitch angle) between the partitions (73) adjacent to each other in the circumferential direction of the drive shaft (75) are substantially the same. Further, the high-voltage side port (51) is an abbreviation of the circumferential direction of the drive shaft (75) in the region between two high-voltage side inlet / outlet ports (52,53) belonging to the same first port group (51,52,53). Located in the center. Similarly, the low pressure side port (61) is the circumferential direction of the drive shaft (75) in the region between two low pressure side inlet / outlet ports (62,63) belonging to the same second port group (61,62,63). It is placed in the center of.

FIG. 5 schematically shows the transition of the flow path switching state in the high pressure side three-way valve (50), and FIG. 6 schematically shows the transition of the flow path switching state in the low pressure side three-way valve (60). In FIGS. 5 and 6, the positional relationship between the first flow path group (54,55) and the first port group (51,52,53) while changing the rotation angle of the valve body (71) by 30 °. It also shows how the positional relationship between the second flow path group (64,65) and the second port group (61,62,63) changes. In addition, in FIG. 5 and FIG. 6, the direction in which the fluid can flow is indicated by an arrow.

As shown in FIG. 5, when the high-pressure side three-way valve (50) has one first flow path group (54,55) (that is, the first port group (51, 52, 53)), each first flow path (54,55) has a length slightly shorter than the half circumference of the valve body (71). By changing the position of the first flow path (54,55) according to the rotation angle of the valve body (71), between each port (51,52,53) of the first port group (51,52,53). The connection status changes. Specifically, either the high-voltage side port (51) or the high-voltage side inlet / outlet port (52,53) as shown in the (b) state, (c) state, (e) state, and (f) state in FIG. A fluid (heat medium) can flow between these two ports when one faces the same first flow path (54,55).

More specifically, in the states (b) and (c) of FIG. 5, the high-voltage side port (51) and the high-voltage side inlet / outlet port (52) are connected to each other, and the high-voltage side inlet / outlet port (53) is closed. Is. Further, in the states (e) and (f) of FIG. 5, the high-voltage side port (51) and the high-voltage side inlet / outlet port (53) are connected to each other, and the high-voltage side inlet / outlet port (52) is in a closed state. On the other hand, when the two ports do not face the same first flow path (54,55) as in the states (a) and (d) of FIG. 5, any port (51, 52,53) is also closed.

In this way, when the high-pressure side three-way valve (50) has one first flow path group (54,55), the flow path is switched once during the half rotation of the valve body (71). That is, the flow path is switched twice during one rotation of the valve body (71).

Further, as shown in FIG. 6, when the low-pressure side three-way valve (60) has one second flow path group (64,65) (that is, a second port group (61,62,63)), each second The flow path (64,65) has a length slightly shorter than the half circumference of the valve body (71). By changing the position of the second flow path (64,65) according to the rotation angle of the valve body (71), between each port (61,62,63) of the second port group (61,62,63). The connection status changes. Specifically, either the low-voltage side port (61) or the low-voltage side inlet / outlet port (62,63) as shown in the (b) state, (c) state, (e) state, and (f) state in FIG. A fluid (heat medium) can flow between these two ports when one faces the same second flow path (64,65).

More specifically, in the states (b) and (c) of FIG. 6, the low-voltage side port (61) and the low-voltage side inlet / outlet port (63) are connected to each other, and the low-voltage side inlet / outlet port (62) is closed. Is. Further, in the states (e) and (f) of FIG. 6, the low-voltage side port (61) and the low-voltage side inlet / outlet port (62) are connected to each other, and the low-voltage side inlet / outlet port (63) is in a closed state. On the other hand, when the two ports do not face the same second flow path (64, 65) as in the states (a) and (d) of FIG. 6, either port (61, 62,63) is also closed.

As described above, when the low-pressure side three-way valve (60) has one second flow path group (64,65), the flow path is switched once during the half rotation of the valve body (71). That is, the flow path is switched twice during one rotation of the valve body (71).

As shown in the states (b) and (c) of FIGS. 5 and 6, the high-pressure side port (51) and the high-pressure side inlet / outlet port (in the high-pressure side three-way valve (50) through the first flow path (55). When communicating with 52), in the low pressure side three-way valve (60), the low pressure side port (61) and the low pressure side through the second flow path (64) blocked from the first flow path (55) by the partition (73). It communicates with the inlet / outlet port (63) (the state of communication shown by the broken lines of the high-pressure side three-way valve (50) and the low-pressure side three-way valve (60) in FIG. 1). Therefore, fluid leakage in the circumferential direction of the drive shaft (75) is suppressed. Further, in these states, for example, the low pressure side inlet / outlet port (62) communicating with the second flow path (65) located at the same circumferential direction as the first flow path (55) on the high pressure side, and the first flow path. The high-pressure side inlet / outlet port (52) communicating with (55) is connected to the outside of the three-way valve, and communicates with the first flow path (54) located at the same circumferential position as the second flow path (64) on the low pressure side. The high-pressure side inlet / outlet port (53) and the low-pressure side inlet / outlet port (63) communicating with the second flow path (64) are connected outside the three-way valve (see FIG. 1). As a result, the first flow path (55) and the second flow path (65) located between the same pair of partitions (73) form a pressure equalizing space in which the drive shaft (75) communicates in the axial direction. The first flow path (54) and the second flow path (64) located between the same pair of partitions (73) form a pressure equalizing space that communicates with the drive shaft (75) in the axial direction. Therefore, fluid leakage in the axial direction of the drive shaft (75) is suppressed without using a seal member.

Further, as shown in the states (e) and (f) of FIGS. 5 and 6, the high pressure side port (51) and the high pressure side inlet / outlet port (in the high pressure side three-way valve (50) through the first flow path (54) When communicating with 53), in the low pressure side three-way valve (60), the low pressure side port (61) and the low pressure side through the second flow path (65) blocked from the first flow path (54) by the partition (73). It communicates with the inlet / outlet port (62) (communication state shown by the solid line of the high pressure side three-way valve (50) and the low pressure side three-way valve (60) in FIG. 1). Therefore, fluid leakage in the circumferential direction of the drive shaft (75) is suppressed. Further, in these states, for example, the low-voltage side inlet / outlet port (63) communicating with the second flow path (64) located at the same circumferential direction as the first flow path (54) on the high-voltage side, and the first flow path. The high-pressure side inlet / outlet port (53) communicating with (54) is connected to the outside of the three-way valve, and communicates with the first flow path (55) located at the same circumferential position as the second flow path (65) on the low pressure side. The high pressure side inlet / outlet port (52) and the low pressure side inlet / outlet port (62) communicating with the second flow path (65) are connected outside the three-way valve (see FIG. 1). As a result, the first flow path (54) and the second flow path (64) located between the same pair of partitions (73) form a pressure equalizing space in which the drive shaft (75) communicates in the axial direction. The first flow path (55) and the second flow path (65) located between the same pair of partitions (73) form a pressure equalizing space that communicates with the drive shaft (75) in the axial direction. Therefore, fluid leakage in the axial direction of the drive shaft (75) is suppressed without using a seal member.

<Control device>
The control device (80) includes a microcomputer and a memory device in which software for operating the microcomputer is stored. The control device (80) controls the magnetic field modulation of the magnetic refrigeration unit (20) and controls the motor of the valve body (71). That is, the control device (80) switches between the first modulation operation and the second modulation operation in the magnetic refrigeration unit (20), and the flow path in the high pressure side three-way valve (50) and the low pressure side three-way valve (60). Make a switch.

<Connection of components>
As shown in FIG. 1, with respect to the first port group (51,52,53) of the high pressure side three-way valve (50), the high pressure side port (51) is connected to the outflow end of the high temperature heat exchanger (42). The high-pressure side inlet / outlet port (52) is connected to the fourth port (P4) of the magnetic refrigeration unit (20-1), and the high-pressure side inlet / outlet port (53) is the fourth port (20-2) of the magnetic refrigeration unit (20-2). Connected to P4). That is, the high-pressure side three-way valve (50) selectively selects the outflow end of the high-temperature heat exchanger (42) to the fourth port (P4) of any of the two magnetic refrigeration units (20-1,20-2). Connect to.

Further, as shown in FIG. 1, regarding the second port group (61,62,63) of the low-pressure side three-way valve (60), the low-pressure side port (61) is connected to the high-temperature heat exchanger (42) through the pump (30). The low pressure side inlet / outlet port (62) is connected to the third port (P3) of the magnetic refrigeration unit (20-1), and the low pressure side inlet / outlet port (63) is connected to the magnetic refrigeration unit (20-). It is connected to the 3rd port (P3) of 2). That is, the low pressure side three-way valve (50) selectively selects the third port (P3) of either of the two magnetic refrigeration units (20-1, 20-2) as the inflow end of the high temperature heat exchanger (42). Connect to.

Further, as shown in FIG. 1, the inflow end of the low temperature heat exchanger (41) is located on the outflow end side of each of the first check valves (25) of the magnetic refrigeration units (20-1) and (20-2). It is connected. Further, the outflow end of the low temperature heat exchanger (41) is connected to the inflow end side of each of the second check valves (26) of the magnetic refrigeration unit (20-1) and (20-2).

<Driving operation>
In the following, the flow of the heat medium during the operation of the magnetic refrigerating apparatus (10) will be described first, and then the heat exchange performed under the flow will be described.

-Flow of heat medium-
In the magnetic refrigeration device (10), the control device (80) switches the flow path in the high-pressure side three-way valve (50) and the low-pressure side three-way valve (60), so that the flow of the heat medium in the heat medium circuit (11) flows. , It is alternately controlled to one of the two modes described below (hereinafter, referred to as a first flow mode and a second flow mode).

In the first flow mode, the heat medium is passed through the high-pressure side three-way valve (50) and the low-pressure side three-way valve (60) in FIG. 1 as shown by the solid line. In order to realize the first flow mode, in the magnetic refrigerating apparatus (10), the third port (P3) of the magnetic refrigerating unit (20-1) and the inflow end of the high temperature heat exchanger (42) are connected so as to be connected. In addition, the low-pressure side three-way valve (60) is switched by the control device (80). Further, in the first flow mode, the high pressure side is provided by the control device (80) so that the outflow end of the high temperature heat exchanger (42) and the fourth port (P4) of the magnetic refrigeration unit (20-2) are connected. The three-way valve (50) is switched. FIG. 7 is a diagram schematically showing a flow path switching state of the high pressure side three-way valve (50) and the low pressure side three-way valve (60) in the first flow mode.

When the pump (30) is operated in this state, the heat medium discharged from the pump (30) passes through the high temperature heat exchanger (42) to the fourth port (20-2) of the magnetic refrigeration unit (20-2). Enter P4) and pass through the temperature control flow path. After that, the heat medium flows out from the first port (P1) of the magnetic refrigeration unit (20-2). The heat medium flowing out from the first port (P1) enters the low temperature heat exchanger (41) via the first check valve (25).

The heat medium that has passed through the low temperature heat exchanger (41) enters the magnetic refrigeration unit (20-1) via its second check valve (26) and second port (P2). In the first flow mode, the pressure of the heat medium flowing out from the low temperature heat exchanger (41) due to the pressure loss in the low temperature heat exchanger (41) is the pressure of the second port (20-2) of the magnetic refrigeration unit (20-2). It becomes lower than the pressure of the heat medium in P2). Therefore, even if the outflow end of the low temperature heat exchanger (41) is connected to the second port (P2) of the magnetic refrigeration unit (20-2), the heat medium is magnetic from the second port (P2). It does not flow into the refrigeration unit (20-2).

Then, the heat medium that has passed through the magnetic refrigeration unit (20-1) flows out from the third port (P3) of the magnetic refrigeration unit (20-1), and flows out through the low-pressure side three-way valve (60) to the pump (60-1). Inhaled in 30).

On the other hand, in the second flow mode, the heat medium is flowed through the high pressure side three-way valve (50) and the low pressure side three-way valve (60) in FIG. 1 as shown by the broken line. In order to realize the second flow mode, in the magnetic refrigerating apparatus (10), the third port (P3) of the magnetic refrigerating unit (20-2) and the inflow end of the high temperature heat exchanger (42) are connected so as to be connected. In addition, the low-pressure side three-way valve (60) is switched by the control device (80). Further, in the second flow mode, the high pressure side is provided by the control device (80) so that the outflow end of the high temperature heat exchanger (42) and the fourth port (P4) of the magnetic refrigeration unit (20-1) are connected. The three-way valve (50) is switched. FIG. 8 is a diagram schematically showing a flow path switching state of the high pressure side three-way valve (50) and the low pressure side three-way valve (60) in the second flow mode.

When the pump (30) is operated in this state, the heat medium discharged from the pump (30) passes through the high temperature heat exchanger (42) to the fourth port (20-1) of the magnetic refrigeration unit (20-1). Enter P4) and pass through the temperature control flow path. After that, the heat medium flows out from the first port (P1) of the magnetic refrigeration unit (20-1). The heat medium flowing out from the first port (P1) enters the low temperature heat exchanger (41) via the first check valve (25).

The heat medium that has passed through the low temperature heat exchanger (41) enters the magnetic refrigeration unit (20-2) via its second check valve (26) and second port (P2). In the second flow mode, the pressure of the heat medium flowing out of the low temperature heat exchanger (41) due to the pressure loss in the low temperature heat exchanger (41) is the pressure of the second port (20-1) of the magnetic refrigeration unit (20-1). It becomes lower than the pressure of the heat medium in P2). Therefore, even if the outflow end of the low temperature heat exchanger (41) is connected to the second port (P2) of the magnetic refrigeration unit (20-1), the heat medium is magnetic from the second port (P2). It does not flow into the refrigeration unit (20-1).

Then, the heat medium that has passed through the magnetic refrigeration unit (20-2) flows out from the third port (P3) of the magnetic refrigeration unit (20-2), and is pumped (60) via the low-pressure side three-way valve (60). Inhaled in 30).

The first flow mode and the second flow mode described above are alternately switched by the control device (80) at a predetermined cycle during the operation of the magnetic refrigeration device (10).

-Heat exchange in each flow mode-
In the magnetic refrigeration apparatus (10), each magnetic refrigeration unit ( The magnetic field modulator of 20) is controlled by the control device (80).

For example, in the first flow mode, the magnetic refrigeration unit (20-1) performs the first modulation operation (heat generation), and the magnetic refrigeration unit (20-2) performs the second modulation operation (endothermic). Each magnetic field modulator is controlled. Further, in the second flow mode, contrary to the case of the first flow mode, the second modulation operation (endothermic) is performed in the magnetic refrigeration unit (20-1), and the first in the magnetic refrigeration unit (20-2). Each magnetic field modulator is controlled so that the modulation operation (heat generation) is performed.

That is, in the magnetic refrigerating apparatus (10), when the magnetic working substance (23) generates heat in one magnetic refrigerating unit (20), the magnetic working substance (23) is generated in the other magnetic refrigerating unit (20). It absorbs heat. Then, the heat medium flowing out from the magnetic refrigeration unit (20) on the side where the magnetic work material (23) is generating heat is supplied to the high temperature heat exchanger (42), and the side where the magnetic work material (23) is endothermic. The heat medium flowing out of the magnetic refrigeration unit (20) is supplied to the low temperature heat exchanger (41).

In each magnetic refrigeration unit (20), heat exchange is performed between the heat medium and the magnetic working substance (23) in both the first and second flow modes. Further, in the low-temperature and high-temperature heat exchangers (41, 42), heat exchange is performed between the heat medium and a predetermined target (for example, a secondary refrigerant or air). Therefore, the first flow mode and the second flow mode are alternately switched, and in synchronization with this, the first modulation operation (heat generation) and the second modulation operation (endothermic) in each magnetic refrigeration unit (20) are alternately switched. In the low temperature and high temperature heat exchangers (41,42), heat exchange is continuously performed.

<Effect of embodiment>
As described above, according to the present embodiment, the first flow path (54,55) in which the ports are selectively communicated with each other by the high pressure side three-way valve (50) and the ports are connected with each other by the low pressure side three-way valve (60). A second flow path (64,65) for selectively communicating with the valve body (71) is formed in the circumferential direction of the same valve body (71). Therefore, even if the degree of adhesion between the valve box (70) and the valve body (71) is not increased, the pressure difference between the high-pressure side three-way valve (50) and the low-pressure side three-way valve (60) causes the circumferential direction. Fluid leakage can be suppressed. Therefore, it is possible to provide a rotary valve type three-way valve which can suppress fluid leakage and power loss with a simple structure and has high durability.

On the other hand, as in the comparative example shown in FIG. 16, the first flow path (54,55) and the second flow path (64,65) are separated into separate valve bodies (71-1) and (71-2). As shown by the double-headed arrow in the figure, the high-pressure side three-way valve (50) and the low-pressure side three-way valve (50) and the low-pressure side three-way along the facing surfaces of the valve bodies (71-1) and (71-2). Circumferential fluid leakage occurs due to the pressure difference with the valve (60). For such a liquid leak in the circumferential direction, the first flow path (54,55) and the second flow path (64,65) are provided in the same valve body (71) as in the present embodiment shown in FIG. Can be resolved by. In FIG. 16, the same components as those of the rotary valve type three-way valve of the present embodiment shown in FIG. 2 are designated by the same reference numerals.

Further, according to the present embodiment, the first port group (51,52,53) has a drive shaft (75) so that the high-voltage side port (51) is located between the two high-voltage side inlet / outlet ports (52,53). The second port group (61,62,63) is arranged in the circumferential direction of), and the drive shaft (75) is arranged so that the low pressure side port (61) is located between the two low pressure side inlet / outlet ports (62,63). ) Is arranged in the circumferential direction. Further, the first port group (51,52,53) and the second port group (61,62,63) are provided in the valve box (70) in the circumferential direction of the drive shaft (75), respectively. Further, the high-pressure side three-way valve (50) uses the first flow path group (54,55), which is a set of two adjacent first flow paths (54,55), as a drive shaft (74,55) in the valve body (71). The low-pressure side three-way valve (60), which is provided in the circumferential direction of 75), has a second flow path group (64,65) consisting of two adjacent second flow paths (64,65) as a valve body. It is held in the circumferential direction of the drive shaft (75) in (71). Therefore, the flow path can be switched twice while the valve body (71) makes one rotation.

Further, according to the present embodiment, the high pressure side port (51) of the first port group (51,52,53) and the low pressure side port (61) of the second port group (61,62,63) are driven. They are arranged at different angles of approximately 180 ° in the circumferential direction of the axis (75). Further, the first flow path group (54,55) of the high-pressure side three-way valve (50) and the second flow path group (64,65) of the low-pressure side three-way valve (60) are from the axial direction of the drive shaft (75). As you can see, they are arranged so that their positions in the circumferential direction are almost the same. Further, of the first flow path group (54,55) of the high-pressure side three-way valve (50), the first flow path (54,55) that communicates the high-pressure side port (51) and the high-pressure side inlet / outlet port (52,53). ) And the second flow path group (64,65) of the low-pressure side three-way valve (60) that does not communicate with the low-pressure side port (61) and the low-pressure side inlet / outlet port (62,63). 65) is arranged so that the positions in the circumferential direction are substantially the same when viewed from the axial direction of the drive shaft (75). Further, of the first flow path group (54,55) of the high-pressure side three-way valve (50), the first flow path (54,55) that does not allow the high-pressure side port (51) and the high-pressure side inlet / outlet port (52,53) to communicate with each other. ) And the second flow path group (64,65) of the low-pressure side three-way valve (60) that communicates the low-pressure side port (61) and the low-pressure side inlet / outlet port (62,63). 65) is arranged so that the positions in the circumferential direction are substantially the same when viewed from the axial direction of the drive shaft (75). Therefore, in the high-pressure side three-way valve (50), in the first flow path (54,55) that communicates the high-pressure side port (51) and the high-pressure side inlet / outlet port (52,53), and in the low-pressure side three-way valve (60). The second flow path (64,65) that does not communicate the low-pressure side port (61) and the low-pressure side inlet / outlet port (62,63) is connected outside the valve, and the high-pressure side port (50) is connected to the high-pressure side three-way valve (50). The first flow path (54,55) that does not communicate between the high pressure side inlet / outlet port (52,53) and the low pressure side port (61) and the low pressure side inlet / outlet port (62,63) in the low pressure side three-way valve (60). By connecting the second flow path (64,65) that communicates with) to the outside of the valve, the first flow path (54,55) and the second flow path (64,65) whose positions in the circumferential direction are substantially the same. ) And can be equalized. Therefore, fluid leakage in the axial direction can be suppressed without using a sealing member.

Further, according to the present embodiment, the valve body (71) divides the space between the valve body (71) and the valve box (70) into two evenly in the circumferential direction, and the first flow path group (54). , 55) and two partitions (73) forming a second channel group (64,65). Therefore, in each of the high-pressure side three-way valve (50) and the low-pressure side three-way valve (60), fluid leakage in the circumferential direction can be suppressed by the partition (73).

Further, according to the present embodiment, the first flow path (54,55) and the second flow path (64,65) located between the same pair of partitions (73) are in the axial direction of the drive shaft (75). It constitutes a communication pressure equalizing space. Therefore, axial fluid leakage occurs between the first flow path (54,55) and the second flow path (64,65) sandwiched by the same pair of partitions (73) without using a sealing member. Can be suppressed.

Further, according to the present embodiment, the first flow path group (54,55) and the second flow path group (64,65) are the first port group (51,52,53) in the axial direction of the drive shaft (75). ) And a groove (71a, 71b, 71c, 71d) formed along the circumferential direction of the drive shaft (75) in the valve body (71) at a position corresponding to the second port group (61,62,63). .. Therefore, the first flow path group (54,55) and the second flow path group (64,65) can be easily formed.

Further, according to the present embodiment, the two high-pressure side entrance ports (52,53) and the two low-pressure side entrance ports (62,63) are arranged at substantially the same positions in the circumferential direction of the drive shaft (75). Arrangement angle between entrance / exit ports (52,53,62,63) adjacent to each other in the circumferential direction of the drive shaft (75) in the first port group (51,52,53) and the second port group (61,62,63). The difference and the difference in the arrangement angle between the partitions (73) adjacent to each other in the circumferential direction of the drive shaft (75) are substantially the same. Therefore, the flow path switching control can be easily performed.

Further, according to the present embodiment, the high-voltage side port (51) and the low-voltage side port (61) are abbreviated in the circumferential direction of the drive shaft (75) in the region between the corresponding inlet / outlet ports (52,53,62,63), respectively. Located in the center. Therefore, the flow path switching control can be performed more easily.

<< Modification 1 >>
This modification differs from the above embodiment in that it has two first port groups (51,52,53) and two second port groups (61,62,63) and a first channel group (54). , 55) and two second flow path groups (64, 65), respectively.

Although not shown, in this modification, each magnetic refrigeration unit (20) has two beds (22). In the high-pressure side three-way valve (50), the high-pressure side ports (51A, 51B) are connected to the outflow ends of the high-temperature heat exchanger (42), respectively, and the high-pressure side inlet / outlet ports (52A, 52B) are magnetic refrigeration units. It is connected to the 4th port (P4) of each bed (22) of (20-1), and the high pressure side entrance port (53A, 53B) is the 4th port (22) of each bed (22) of the magnetic refrigeration unit (20-2). Connected to port (P4). In the low-voltage side three-way valve (60), the low-voltage side ports (61A, 61B) are connected to the inflow end of the high-temperature heat exchanger (42) through the pump (30), respectively, and the low-voltage side inlet / outlet ports (62A, 62B). Is connected to the 3rd port (P3) of each bed (22) of the magnetic refrigeration unit (20-1), and the low-voltage side inlet / outlet ports (63A, 63B) are connected to each bed (20-2) of the magnetic refrigeration unit (20-2). It is connected to the 3rd port (P3) of 22).

FIG. 9 schematically shows the transition of the flow path switching state in the high pressure side three-way valve (50) of this modified example, and FIG. 10 shows the flow path switching state of the low pressure side three-way valve (60) of this modified example. The transition of is schematically shown. In FIGS. 9 and 10, the positions of the first flow path group (54,55) and the first port group (51,52,53) are changed by changing the rotation angle of the valve body (71) by 15 °. It shows the relationship and how the positional relationship between each second channel group (64,65) and each second port group (61,62,63) changes. In addition, in FIG. 9 and FIG. 10, the direction in which the fluid can flow is indicated by an arrow.

As shown in FIG. 9, in the high-pressure side three-way valve (50) of this modified example, each first flow path (54A, 55A, 54B, 55B) is slightly shorter than the 1/4 circumference of the valve body (71). Has a length. The position of each first flow path (54A, 55A, 54B, 55B) changes according to the rotation angle of the valve body (71), so that the first port group (51A, 52A, 53A) and the first port group (51B) , 52B, 53B) The connection status between each port changes. Specifically, either the high-voltage side port (51A) or the high-voltage side inlet / outlet port (52A, 53A) as shown in the (b) state, (c) state, (e) state, and (f) state in FIG. A fluid (heat medium) can flow between these two ports when one faces the same first flow path (54A, 55A). Similarly, when any one of the high pressure side port (51B) and the high pressure side inlet / outlet port (52B, 53B) faces the same first flow path (54B, 55B), a fluid (fluid) between these two ports. Heat medium) can be distributed.

More specifically, in the states (b) and (c) of FIG. 9, the high-pressure side port (51A) and the high-pressure side entrance port (52A) are connected to each other, and the high-pressure side entrance port (53A) is closed. Is. Further, the high-voltage side port (51B) and the high-voltage side inlet / outlet port (52B) are connected to each other, and the high-voltage side inlet / outlet port (53B) is in a closed state.

Further, in the states (e) and (f) of FIG. 9, the high-voltage side port (51A) and the high-voltage side inlet / outlet port (53A) are connected to each other, and the high-voltage side inlet / outlet port (52A) is in a closed state. Further, the high-voltage side port (51B) and the high-voltage side inlet / outlet port (53B) are connected to each other, and the high-voltage side inlet / outlet port (52B) is in a closed state.

On the other hand, when the two ports do not face the same first flow path (54A, 55A, 54B, 55B) as in the states (a) and (d) of FIG. The ports (51A, 52A, 53A, 51B, 52B, 53B) are also closed.

In this way, when the high-pressure side three-way valve (50) has two first flow path groups (54,55), the flow path is switched once during 1/4 rotation of the valve body (71). It is said. That is, the flow path is switched four times during one rotation of the valve body (71). Therefore, the rotation speed of the valve body (71) can be halved even though the flow path is switched the same number of times as in the above embodiment.

Further, as shown in FIG. 10, in the low-pressure side three-way valve (60) of this modified example, each second flow path (64A, 65A, 64B, 65B) is more than a quarter circumference of the valve body (71). Has a slightly shorter length. The position of each second flow path (64A, 65A, 64B, 65B) changes according to the rotation angle of the valve body (71), so that the second port group (61A, 62A, 63A) and the second port group (61B) , 62B, 63B) The connection status between each port changes. Specifically, either the low-voltage side port (61A) or the low-voltage side inlet / outlet port (62A, 63A) as shown in the (b) state, (c) state, (e) state, and (f) state in FIG. A fluid (heat medium) can flow between these two ports when one faces the same second flow path (64A, 65A). Similarly, when any one of the high pressure side port (61B) and the high pressure side inlet / outlet port (62B, 63B) faces the same first flow path (64B, 65B), a fluid (fluid) between these two ports. Heat medium) can be distributed.

More specifically, in the states (b) and (c) of FIG. 10, the low-voltage side port (61A) and the low-voltage side inlet / outlet port (63A) are connected to each other, and the low-voltage side inlet / outlet port (62A) is closed. Is. Further, the low-voltage side port (61B) and the low-voltage side inlet / outlet port (63B) are connected to each other, and the low-voltage side inlet / outlet port (62B) is in a closed state.

Further, in the states (e) and (f) of FIG. 10, the low-voltage side port (61A) and the low-voltage side inlet / outlet port (62A) are connected to each other, and the low-voltage side inlet / outlet port (63A) is in a closed state. Further, the low-voltage side port (61B) and the low-voltage side inlet / outlet port (62B) are connected to each other, and the low-voltage side inlet / outlet port (63B) is in a closed state.

On the other hand, when the two ports do not face the same second flow path (64A, 65A, 64B, 65B) as in the states (a) and (d) of FIG. The ports (61A, 62A, 63A, 61B, 62B, 63B) are also closed.

In this way, when the low-pressure side three-way valve (60) has two second flow path groups (64,65), the flow path is switched once during 1/4 rotation of the valve body (71). Be told. That is, the flow path is switched four times during one rotation of the valve body (71). Therefore, the rotation speed of the valve body (71) can be halved even though the flow path is switched the same number of times as in the above embodiment.

As shown in FIG. 9, in the high-pressure side three-way valve (50) of this modified example, the high-pressure side port (51A) of the first port group (51A, 52A, 53A) and the first port group (51B, 52B). , 53B) and the high-pressure side port (51B) are arranged at an angle approximately 180 ° different from that of the drive shaft (75) in the circumferential direction. Further, the two high-pressure side inlet / outlet ports (52A, 53A) of the first port group (51A, 52A, 53A) sandwich the high-pressure side port (51A), respectively, in the circumferential direction of the drive shaft (75). It is arranged at an angle approximately 45 ° different from (51A). Further, the two high-pressure side inlet / outlet ports (52B, 53B) of the first port group (51B, 52B, 53B) sandwich the high-pressure side port (51B), respectively, in the circumferential direction of the drive shaft (75). It is arranged at an angle approximately 45 ° different from (51B).

Further, as shown in FIG. 10, in the low-pressure side three-way valve (60) of this modified example, the low-pressure side port (61A) of the second port group (61A, 62A, 63A) and the second port group (61B, 62B) , 63B) and the low-voltage side port (61B) are arranged at an angle approximately 180 ° different from that of the drive shaft (75) in the circumferential direction. Further, the two low-voltage side inlet / outlet ports (62A, 63A) of the second port group (61A, 62A, 63A) sandwich the low-voltage side port (61A), respectively, in the circumferential direction of the drive shaft (75). It is arranged at an angle approximately 45 ° different from (61A). Further, the two low-voltage side inlet / outlet ports (62B, 63B) of the second port group (61B, 62B, 63B) sandwich the low-voltage side port (61B), respectively, in the circumferential direction of the drive shaft (75). It is arranged at an angle approximately 45 ° different from (61B).

Further, as shown in FIGS. 9 and 10, the high pressure side port (51A) of the first port group (51A, 52A, 53A) and the low pressure side port (61A) of the second port group (61A, 62A, 63A). Are arranged at approximately 90 ° different angles in the circumferential direction of the drive shaft (75). Further, the high pressure side port (51B) of the first port group (51B, 52B, 53B) and the low pressure side port (61B) of the second port group (61B, 62B, 63B) are the circumferences of the drive shaft (75). Arranged at different angles by approximately 90 ° in the direction. The first flow path group (54A, 55A) of the high-pressure side three-way valve (50) and the second flow path group (64A, 65A) of the low-pressure side three-way valve (60) are from the axial direction of the drive shaft (75). As you can see, they are arranged so that their positions in the circumferential direction are almost the same. Similarly, the first flow path group (54B, 55B) of the high-pressure side three-way valve (50) and the second flow path group (64B, 65B) of the low-pressure side three-way valve (60) are in the axial direction of the drive shaft (75). It is arranged so that the positions in the circumferential direction are substantially the same when viewed from the above.

Further, as shown in FIGS. 9 and 10, in this modification, the space between the valve body (71) and the valve box (70) is divided into four evenly in the circumferential direction. A partition (73) is provided on the valve body (71). As a result, two first flow path groups (54A, 55A) and (54B, 55B) and two second flow path groups (64A, 65A) and (64B, 65B) are formed. As will be described later, the first flow path (54A, 55A, 54B, 55B) and the second flow path (64A, 65A, 64B, 65B) located between the same pair of partitions (73) are driven shafts (75). ) Constructs a pressure equalizing space that communicates in the axial direction. Further, the first flow path group (54A, 55A), (54B, 55B) and the second flow path group (64A, 65A), (64B, 65B) are the first port group in the axial direction of the drive shaft (75). Drive shaft (75) on valve body (71) at positions corresponding to (51A, 52A, 53A), (51B, 52B, 53B) and second port group (61A, 62A, 63A), (61B, 62B, 63B) ) Includes grooves (71a, 71b, 71c, 71d) formed along the circumferential direction.

Further, as shown in FIGS. 9 and 10, in this modification, each of the high-pressure side inlet / outlet ports (52A, 53A, 52B, 53B) of the high-pressure side three-way valve (50) and each of the low-pressure side three-way valves (60). The low-voltage side inlet / outlet ports (62A, 63A, 62B, 63B) are arranged at substantially the same position in the circumferential direction of the drive shaft (75). In addition, the circumference of the drive shaft (75) in the first port group (51A, 52A, 53A), (51B, 52B, 53B) and the second port group (61A, 62A, 63A), (61B, 62B, 63B). Difference in arrangement angle between entrance / exit ports (52A, 53A, 52B, 53B, 62A, 63A, 62B, 63B) adjacent to each other in the direction and difference in arrangement angle between partitions (73) adjacent to each other in the circumferential direction of the drive shaft (75). Is substantially the same. As shown in the states (b) and (c) of FIGS. 9 and 10, the high-pressure side port is passed through the first flow path (55A, 55B) in the high-pressure side three-way valve (50). When the (51A, 51B) and the high pressure side inlet / outlet port (52A, 52B) communicate with each other, the low pressure side three-way valve (60) is blocked from the first flow path (55A, 55B) by the partition (73). The low-voltage side port (61A, 61B) and the low-voltage side inlet / outlet port (63A, 63B) communicate with each other through the flow path (64A, 64B). Therefore, fluid leakage in the circumferential direction of the drive shaft (75) is suppressed. Further, in these states, for example, the low pressure side inlet / outlet port (62A, 62B) communicating with the second flow path (65A, 65B) located at the same circumferential position as the first flow path (55A, 55B) on the high pressure side. And the high-pressure side inlet / outlet port (52A, 52B) communicating with the first flow path (55A, 55B) are connected outside the three-way valve, and the same circumferential direction as the second flow path (64A, 64B) on the low-voltage side. The high-voltage side entrance port (53A, 53B) communicating with the first flow path (54A, 54B) at the position and the low-voltage side entrance port (63A, 63B) communicating with the second flow path (64A, 64B) are on three sides. Connect outside the valve. As a result, the first flow path (55A, 55B) and the second flow path (65A, 65B) located between the same pair of partitions (73) communicate with each other in the axial direction of the drive shaft (75). The first flow path (54A, 54B) and the second flow path (64A, 64B) located between the same pair of partitions (73) communicate with each other in the axial direction of the drive shaft (75). It constitutes a pressure space. Therefore, fluid leakage in the axial direction of the drive shaft (75) is suppressed without using a seal member.

Further, as shown in the states (e) and (f) of FIGS. 9 and 10, the high pressure side port (51A, 51B) and the high pressure side port (51A, 51B) and the high pressure side port (51A, 51B) pass through the first flow path (54A, 54B) in the high pressure side three-way valve (50). When communicating with the side inlet / outlet ports (53A, 53B), in the low pressure side three-way valve (60), the second flow path (65A, 65B) blocked from the first flow path (54A, 54B) by the partition (73). The low-voltage side port (61A, 61B) and the low-voltage side entrance / exit port (62A, 62B) communicate with each other. Therefore, fluid leakage in the circumferential direction of the drive shaft (75) is suppressed. Further, in these states, for example, the low pressure side inlet / outlet port (63A, 63B) communicating with the second flow path (64A, 64B) located at the same circumferential position as the first flow path (54A, 54B) on the high pressure side. And the high-pressure side inlet / outlet port (53A, 53B) communicating with the first flow path (54A, 54B) are connected outside the three-way valve, and the same circumferential direction as the second flow path (65A, 65B) on the low-voltage side. The high-voltage side entrance port (52A, 52B) communicating with the first flow path (55A, 55B) at the position and the low-voltage side entrance port (62A, 62B) communicating with the second flow path (65A, 65B) are on three sides. Connect outside the valve. As a result, the first flow path (54A, 54B) and the second flow path (64A, 64B) located between the same pair of partitions (73) communicate with each other in the axial direction of the drive shaft (75). The first flow path (55A, 55B) and the second flow path (65A, 65B) located between the same pair of partitions (73) communicate with each other in the axial direction of the drive shaft (75). It constitutes a pressure space. Therefore, fluid leakage in the axial direction of the drive shaft (75) is suppressed without using a seal member.

<Effect of Modification 1>
According to the first modification described above, the same effect as that of the above-described embodiment can be obtained.

Further, in the above-described embodiment, in each of the high-pressure side three-way valve (50) and the low-pressure side three-way valve (60), the pressure of the flow paths facing each other across the axial center (C) in the radial direction of the drive shaft (75) is applied. It becomes unbalanced. Specifically, when the first flow path (54) of the high-pressure side three-way valve (50) is on the high-pressure side, the first flow path (54) facing the first flow path (54) across the axis (C). 55) is on the low pressure side, and the pressure becomes unbalanced. Further, when the second flow path (64) is on the low pressure side in the low pressure side three-way valve (60), the second flow path (65) facing the second flow path (64) across the axis (C) is It becomes the high pressure side, and the pressure becomes unbalanced. Therefore, pressure may be applied between the drive shaft (75) or the valve body (71) and the valve box (70) to increase friction.

On the other hand, in this modification, the pressures of the flow paths facing each other with the axis (C) in the radial direction of the drive shaft (75) can be balanced. Specifically, when the first flow path (54A) is on the high pressure side in the high pressure side three-way valve (50), the first flow path (54A) facing the first flow path (54A) with the axis (C) in between ( 54B) is also on the high pressure side, and the pressure is in equilibrium. Further, when the second flow path (64A) is on the low pressure side in the low pressure side three-way valve (60), the second flow path (64B) facing the second flow path (64A) with the axis (C) in between is also It is on the low pressure side and the pressure is in equilibrium. Therefore, it is possible to reduce the friction between the drive shaft (75) or the valve body (71) and the valve box (70).

<< Modification 2 >>
FIG. 11 is a vertical cross-sectional view of the rotary valve type three-way valve according to the modified example 2, FIG. 12 is a cross-sectional view of the line XII-XII in FIG. 11 (cross-sectional view of the high-pressure side three-way valve), and FIG. 13 is a cross-sectional view. , FIG. 11 is a cross-sectional view of the line XIII-XIII (cross-sectional view of the low-pressure side three-way valve). In FIGS. 11 to 13, the same components as those of the rotary valve type three-way valve of the embodiment shown in FIGS. 2 to 4 are designated by the same reference numerals.

In the above embodiment, since the pressure of the flow path having the same circumferential position of the drive shaft (75) is set to be equal in each of the high pressure side three-way valve (50) and the low pressure side three-way valve (60), the drive shaft (75) ) Axial, fluid leakage is suppressed. Further, regarding the gap between the upper surface and the lower surface of the valve body (71) and the inner circumference of the valve box (70), fluid leakage is suppressed by making the gap as small as possible. On the other hand, in the circumferential direction of the drive shaft (75), the flow path on the high pressure side and the flow path on the low pressure side are separated by a partition (73), so that the outer circumference of the partition (73) and the inside of the valve box (70) are separated. Fluid may leak to and from the circumference.

Therefore, in this modification, as shown in FIGS. 11 to 13, a movable vane (91) that contacts the inner wall of the valve box (70) is inserted into each partition (73) of the valve body (71). .. Each vane (91) is pressed against the inner wall of the valve box (70) by the high pressure fluid supplied from the high pressure side port (51). Specifically, the valve body (71) is provided with a port (92) for supplying high-pressure fluid at the base of the vane (91). Further, the valve box (70) is connected to the branch hole (70a) for branching the high-pressure fluid from the high-pressure side port (51) and transporting the high-pressure fluid to the upper part of the valve body (71), and the port (70a). A supply hole (70b) for supplying high-pressure fluid from directly above the port (92) to the port (92) is provided.

<Effect of variant 2>
According to the second modification described above, the following effects can be obtained in addition to the same effects as those in the above embodiment. That is, according to this modification, in each of the high pressure side three-way valve (50) and the low pressure side three-way valve (60), the vane (91) can further suppress the fluid leakage in the circumferential direction. Further, since the vane (91) is pressed against the inner wall of the valve box (70) by the high-pressure fluid supplied from the high-pressure side port (51), it is not necessary to use a spring or the like. Further, by providing the valve body (71) with a port (92) for supplying a high-pressure fluid to the base of the vane (91), the high pressure supplied to the base of the vane (91) via the port (92). The fluid allows the vane (91) to be pressed against the inner wall of the valve box (70).

When one vane (91) is provided in one partition (73), although the structure is simple, there is a risk of fluid leakage when switching the flow path. Therefore, for example, as shown in FIG. 14, by providing a plurality of vanes (91) (two in FIG. 14) in one partition (73), fluid leakage is further suppressed even when the flow path is switched. It becomes possible.

<< Other Embodiments >>
In the above-described embodiment (including a modified example, the same applies hereinafter), a rotary valve type three-way valve used in the magnetic refrigeration apparatus (10) shown in FIG. 1 has been described. However, the configuration of the magnetic refrigerating apparatus to be applied is not particularly limited. For example, as shown in FIG. 15, instead of the first check valve (25) and the second check valve (26) of the magnetic refrigeration apparatus (10) shown in FIG. 1, an intermediate high-pressure side three-way valve (110) and An intermediate low pressure side three-way valve (120) may be used. The intermediate high-pressure side three-way valve (110) and the intermediate low-pressure side three-way valve (120) may be laminated so as to share the same valve box and valve body as in the above embodiment.

The intermediate high pressure side three-way valve (110) has an intermediate high pressure side port (111) and two intermediate high pressure side inlet / outlet ports (112,113) that selectively communicate with the intermediate high pressure side port (111). The intermediate high pressure side port (111) is connected to the inflow end of the low temperature heat exchanger (41), and the intermediate high pressure side inlet / outlet port (112) is connected to the first port (P1) of the magnetic refrigeration unit (20-2). The intermediate high pressure side inlet / outlet port (113) is connected to the first port (P1) of the magnetic refrigeration unit (20-1). That is, the intermediate high-pressure side three-way valve (110) selects the first port (P1) of either of the two magnetic refrigeration units (20-1, 20-2) as the inflow end of the low-temperature heat exchanger (41). Connect to. In the intermediate high pressure side three-way valve (110), fluid flows from any of the intermediate high pressure side inlet / outlet ports (112,113) to the intermediate high pressure side port (111).

The intermediate low pressure side three-way valve (120) has an intermediate low pressure side port (121) and two intermediate low pressure side inlet / outlet ports (122,123) that selectively communicate with the intermediate low pressure side port (121). The intermediate low pressure side port (121) is connected to the outflow end of the low temperature heat exchanger (41), and the intermediate low pressure side inlet / outlet port (122) is connected to the second port (P2) of the magnetic refrigeration unit (20-2). The intermediate low pressure side inlet / outlet port (123) is connected to the second port (P2) of the magnetic refrigeration unit (20-1). That is, the intermediate low-pressure side three-way valve (120) selects the outflow end of the low-temperature heat exchanger (41) as the second port (P2) of either of the two magnetic refrigeration units (20-1,20-2). Connect to. In the intermediate low pressure side three-way valve (120), fluid flows from the intermediate low pressure side port (121) to any of the intermediate low pressure side inlet / outlet ports (122,123).

Further, in the above embodiment, two three-way valves, a high-pressure side three-way valve (50) and a low-pressure side three-way valve (60), are laminated, but three or more three-way valves may be laminated.

Further, in the above-described embodiment, the first port group (51,52,53) and the second port group (61,62,63) and the first flow path group (54,55) and the second flow path group (64, Although one or two of 65) are provided respectively, three or more of these may be provided respectively.

Further, in the above-described embodiment, two or more first flow paths (54,55) and two or more second flow paths (64, 65) are provided, but instead of this, one first port group (each one) (1st port group). A first flow path (54,55) and a second flow path (64, 65) may be provided for each of the 51, 52, 53) and the second port group (61, 62, 63). ..

Although the embodiments and modifications have been described above, it will be understood that various modifications of the forms and details are possible without departing from the purpose and scope of the claims. Further, the above embodiments and modifications may be appropriately combined or replaced as long as the functions of the subject of the present disclosure are not impaired.

As described above, the present disclosure is useful for rotary valve type three-way valves.

10 Magnetic refrigeration system
50 High pressure side three-way valve
51 High pressure side port
52,53 High pressure side doorway port
54,55 1st channel
60 Low pressure side three-way valve
61 Low pressure side port
62,63 Low pressure side doorway port
64,65 2nd channel
70 valve box
71 Valve body
71a, 71b, 71c, 71d groove
73 dividers
75 drive shaft
91 Vane
92 ports

Claims (11)

A valve box (70) having multiple ports (51,52,53,61,62,63) for fluids to enter and exit, and a rotational position located within the valve box (70) and around a drive shaft (75). A valve body (71) having a flow path (54,55,64,65) for selectively communicating between the plurality of ports (51,52,53,61,62,63) is provided, and magnetic refrigeration is provided. A rotary valve type three-way valve used in the device (10).
It has a structure in which the high-pressure side three-way valve (50) and the low-pressure side three-way valve (60) are at least laminated.
The high-pressure side three-way valve (50) is a first port group (51, 53) composed of a high-pressure side port (51) and two high-pressure side inlet / outlet ports (52,53) that selectively communicate with the high-pressure side port (51). Have at least one 52,53)
The low pressure side three-way valve (60) is a second port group (61, 63) composed of a low pressure side port (61) and two low pressure side inlet / outlet ports (62,63) that selectively communicate with the low pressure side port (61). Have at least one 62,63)
The first port group (51,52,53) and the second port group (61,62,63) are provided in the same valve box (70).
The high-pressure side three-way valve (50) is a first flow path (54,55) that selectively communicates the high-pressure side port (51) with any one of the two high-pressure side inlet / outlet ports (52,53). At least one in the circumferential direction of the drive shaft (75).
The low pressure side three-way valve (60) is a second flow path (64, 65) that selectively communicates the low pressure side port (61) with any one of the two low pressure side inlet / outlet ports (62,63). At least one in the circumferential direction of the drive shaft (75).
A rotary valve type three-way valve characterized in that the first flow path (54,55) and the second flow path (64,65) are formed in the same valve body (71). In claim 1,
The first port group (51,52,53) is in the circumferential direction of the drive shaft (75) so that the high-pressure side port (51) is located between the two high-pressure side inlet / outlet ports (52,53). Placed in
The second port group (61,62,63) is in the circumferential direction of the drive shaft (75) so that the low-voltage side port (61) is located between the two low-voltage side inlet / outlet ports (62,63). Placed in
The first port group (51,52,53) and the second port group (61,62,63) each have n (n: natural numbers) of the drive shaft (75) in the valve box (70). Provided in the circumferential direction
The high-pressure side three-way valve (50) drives the first flow path group (54,55), which is a set of two adjacent first flow paths (54,55), in the valve body (71). It has n pieces in the circumferential direction of the shaft (75),
The low-pressure side three-way valve (60) drives a second flow path group (64, 65), which is a set of two adjacent second flow paths (64, 65), in the valve body (71). A rotary valve type three-way valve characterized by having n pieces in the circumferential direction of the shaft (75). In claim 2,
The high-pressure side port (51) of the first port group (51,52,53) and the low-pressure side port (61) of the second port group (61,62,63) are described as described above. Arranged at approximately 180 ° / n different angles in the circumferential direction of the drive shaft (75).
The first flow path group (54,55) of the high-pressure side three-way valve (50) and the second flow path group (64,65) of the low-pressure side three-way valve (60) are of the drive shaft (75). Arranged so that the positions in the circumferential direction are almost the same when viewed from the axial direction.
The first flow path (54,55) of the high-pressure side three-way valve (50) that communicates the high-pressure side port (51) and the high-pressure side inlet / outlet port (52,53). 54,55) and the low pressure side port (61) and the low pressure side inlet / outlet port (62,63) of the second flow path group (64,65) of the low pressure side three-way valve (60) are not communicated with each other. The second flow path (64,65) is arranged so that the positions in the circumferential direction substantially coincide with each other when viewed from the axial direction of the drive shaft (75).
Of the first flow path group (54,55) of the high-pressure side three-way valve (50), the first flow path (51) that does not allow the high-pressure side port (51) and the high-pressure side inlet / outlet port (52,53) to communicate with each other. 54,55) and the low pressure side port (61) and the low pressure side inlet / outlet port (62,63) of the second flow path group (64,65) of the low pressure side three-way valve (60) are communicated with each other. The second flow path (64, 65) is a rotary valve type three-way valve characterized in that the second flow path (64, 65) is arranged so that the positions in the circumferential direction are substantially the same when viewed from the axial direction of the drive shaft (75). In claim 3,
The valve body (71) divides the space between the valve body (71) and the valve box (70) evenly into 2n pieces in the circumferential direction, and n pieces of each of the first flow path groups (54). , 55) and a rotary valve type three-way valve having 2n partitions (73) forming the second flow path group (64,65). In claim 4,
The first flow path (54,55) and the second flow path (64,65) located between the same pair of partitions (73) among the 2n partitions (73) are the drive shafts (64,65). A rotary valve type three-way valve characterized by forming a pressure equalizing space that communicates in the axial direction of 75). In claim 4 or 5,
The n first flow path groups (54,55) and the second flow path group (64,65) are the first port group (51,52,53) in the axial direction of the drive shaft (75). And a groove (71a, 71b, 71c, 71d) formed along the circumferential direction of the drive shaft (75) in the valve body (71) at a position corresponding to the second port group (61,62,63). A rotary valve type three-way valve characterized by including. In any one of claims 4 to 6,
The high-voltage side inlet / outlet ports (52,53) and the low-voltage side inlet / outlet ports (62,63) are arranged at substantially the same positions in the circumferential direction of the drive shaft (75).
In the first port group (51,52,53) and the second port group (61,62,63), the inlet / outlet ports (52,53,62,63) adjacent to each other in the circumferential direction of the drive shaft (75) The difference in the arrangement angle of the two partitions (73) and the difference in the arrangement angle between the partitions (73) adjacent to each other in the circumferential direction of the drive shaft (75) are substantially the same. Type three-way valve. In claim 7,
The high-pressure side port (51) and the low-pressure side port (61) are respectively arranged substantially in the circumferential center of the drive shaft (75) in the corresponding entrance / exit port (52,53,62,63) inter-region. A rotary valve type three-way valve characterized by this. In any one of claims 4 to 8,
A rotary valve type three-way valve characterized in that at least one vane (91) in contact with the inner wall of the valve box (70) is used for the 2n partitions (73). In claim 9.
The vane (91) is a rotary valve type three-way valve characterized in that the high-pressure fluid supplied from the high-pressure side port (51) presses against the inner wall of the valve box (70). In claim 10,
A rotary valve type three-way valve characterized in that the valve body (71) is provided with a port (92) for supplying the high-pressure fluid at the base of the vane (91).

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