JPH07107385B2 - Swash plate type compressor - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a swash plate compressor used in an air conditioning apparatus that also serves as an air conditioner.

(Prior Art) In a conventional swash plate compressor, as shown in FIG.
Rotor (b) through casing (b) in casing (a)
Is rotatably supported, and a piston (e) is fitted into the cylinder bore (d) penetrating the rotor (c) in the rotor (c) to form a compression chamber (f) in the upper portion of the cylinder bore (d). The swash plate (the swash plate on the inner bottom of the casing (a) faces the end face of the piston (e) of the rotor (c) at a predetermined distance, and the end face of the piston (e) slides. g) is provided in an inclined manner,
A suction port (h) and a discharge port (i) are provided between the upper part of the casing (a) and the compression chamber (f) side of the rotor (c).
The valve plate (j) opened to one is interposed. Then, when the rotor (c) is rotated, the piston (e) is tilted by the swash plate (g) to cause the cylinder bore (d).
The liquid is moved up and down, and the liquid flowing into the compression chamber (f) from the suction port (h) is compressed and discharged from the discharge port (i).

(Problems to be Solved by the Invention) In the swash plate compressor described above, only one suction port (h) and one discharge port (i) are provided, and the fluid flow direction is always constant. . However, in this case, as shown in FIG. 6, an air conditioner for both heating and cooling having a swash plate compressor (c), an outdoor heat exchanger (1), an expansion valve (m) and an indoor heat exchanger (n) is used. As described above, when the swash plate compressor is used in a system in which the circulation direction of the refrigerant, that is, the fluid to be compressed is reversed during cooling and heating, the four-way switching valve (k) is required, and the number of parts is reduced. There is a problem that the number of refrigerant circuits increases and the refrigerant circuit becomes complicated and expensive. In addition, there is a problem in that it is difficult to support the four-way switching valve itself and the piping, and refrigerant may leak from the four-way switching valve (k).

The present invention has been made in view of the above problems, and an object thereof is to provide a compressor main body with a function of a four-way switching valve to achieve multiple functions and to simplify a refrigerant circuit and the like. It is what

(Means for Solving the Problem) In order to solve the above-mentioned problems, the means taken by the invention according to claim (1) is as follows. First, as shown in FIG. 2 and FIG. A rotor (1) supported in a forward and reverse direction via (3) is provided, and a cylinder bore (5) is formed in the rotor (1) so as to penetrate the rotor (1) and the cylinder bore (5). ), A piston (6) slidably fitted in the cylinder bore (5) to form a compression chamber (20) is provided. The piston (6) of the rotor (1) faces the end face of the piston (6) at a predetermined distance, and the piston (6).
A swash plate (7) with which the front end of the sliding contact moves is provided so as to be inclined with respect to the end face. Further, the end face of the rotor (1) on the side of the compression chamber (20) is in close contact with the end face, and the normal position on the normal side is set when the rotor (1) rotates in the forward direction and the fixed position on the reverse side is set when the rotor is rotated in the reverse direction. A valve plate (9) slidable in two fixed positions is provided. Moreover, FIGS. 1 and 3
As shown in the figure, when the valve plate (9) is set to both the forward rotation side fixed position and the reverse rotation side fixed position, at least the most protrusion of the piston (6) with respect to the cylinder bore (5). One suction port (21) communicating with the compression chamber (20) is opened at the position. In addition, when the valve plate (9) is set to the normal position on the normal side of the valve plate (9), the compression chamber (20) communicates with the cylinder bore (5) in the vicinity of the most retracted position of the piston (6). When the normal rotation side discharge port (22) and the reverse rotation side fixed position are set, the reverse rotation side discharge port (23) where the compression chamber (20) communicates near the most retracted position of the piston (6) with respect to the cylinder bore (5). It is configured to open and.

Further, the means taken by the invention according to claim (2) is that in the invention according to claim (1), the valve plate (9) is formed in a substantially oval shape in plan view and is provided slidably in the major axis direction. While the suction port (22) is opened in the central portion in the minor axis direction, the forward rotation side discharge port (22) and the reverse rotation side discharge port (2
3) and are located on both sides of the suction port (21).

(Operation) With the above configuration, in the invention according to claim (1), when the rotor (1) is rotated, the piston (6) is moved by the spring force of the spring (8) in the cylinder bore (5), for example. The cylinder bore (5) rotates along the inclination of the swash plate (7) while being rotated by the main shaft (3) while being pressed by the swash plate (7).
The volume of the compression chamber (20) expands or contracts by reciprocally sliding inside.

During normal rotation of the rotor (1), the valve plate (9) is set to the normal rotation side fixed position, and the suction port (21) and the normal rotation side discharge port (22) are connected to the compression chamber (20). As a result of communication, the fluid flows into the compression chamber (20) from the suction port (21), is compressed, and is then discharged from the forward rotation side discharge port (22).

On the other hand, when the rotor (1) is rotated in the reverse direction, the valve plate (9) is set at the reverse rotation side fixed position. For example, in the invention according to claim (2), the valve plate (9) is slid in the major axis direction. The suction port (21) and the reverse rotation side discharge port (23) are communicated with the compression chamber (20) by being moved to a fixed position on the reverse rotation side, and the fluid flows from the suction port (21) to the compression chamber (20). ), Is compressed, and is then discharged from the reverse rotation side discharge port (23).

Therefore, since the flow direction of the fluid can be reversed by setting the valve plate (9) at the two positions, the compressor itself can be provided with the four-way switching valve function.

(Example) Below, the Example of this invention is described based on drawing.

As shown in FIGS. 2 and 4, (c) is a hermetic swash plate compressor provided in a refrigerant circulation circuit capable of reversible operation in a cooling cycle and a heating cycle, and includes a plurality of pistons ( A motor (M) in which 6), (6), ... Are integrally incorporated is housed in a casing (4). The motor (M) has the stator (2) attached to the side surface of the casing (4) and the rotor (1).
Is inserted into the stator (2), and the rotor (1)
Is supported by the casing (4) via a main shaft (3) in the up-down direction so as to be freely reversible. Further, the rotor (1) is formed with a plurality of cylinder bores (5), (5), ... Penetrating between both end faces, and a piston is provided in the cylinder bores (5), (5) ,. The compression chamber (20) is formed in the upper part of the cylinder bore (5) by slidably fitting the (6) in the vertical direction. The piston (6) is biased downward by a spring (8) provided in the cylinder bore (5).

Further, the swash plate (7) faces the lower end plate (42) in the casing (4) at a predetermined distance from the projecting end surface (lower end surface) of the piston (6) of the rotor (1). The swash plate (7) is formed so that the tip of the piston (6) is slidably moved and is inclined with respect to the lower end surface of the rotor (1).

Further, the valve plate (9) is closely contacted at the upper end face between the upper face plate (41) of the casing (4) and the side end face (upper end face) of the compression chamber (20) of the rotor (1). It is set up. The valve plate (9) is formed of a substantially oval flat plate that is long in a direction perpendicular to the inclination direction of the swash plate (7) and is slidably provided in the major axis direction. As shown in FIG. 1, the valve plate (9) has a normal rotation side fixed position in which the rotor (1) is located on the left side of the valve plate (9) when the rotor (1) rotates clockwise in the forward direction. As shown in FIG. 3, when the rotor (1) is rotated counterclockwise in the counterclockwise direction, the rotor (1) can be moved and set to a fixed position on the reverse side on the right side of the valve plate (9). ing.

Further, the valve plate (9) has one suction port (21), a forward rotation side discharge port (22) communicating with the compression chamber (20) when the rotor (1) rotates in the forward direction, and a compression chamber when rotating in the reverse direction. The reverse rotation side discharge port (23) communicating with (20) and the shaft hole (21
s) and are drilled.

The suction port (21) is formed in a rectangular shape in the central portion of the valve plate (9) over both ends in the minor axis direction, and in any set state of both fixed positions of the valve plate (9). Is also configured to communicate with the compression chamber (20) in the expansion stroke. That is, the compression chamber (20) in the stroke from the vicinity of the most retracted position of the piston (6) to the cylinder bore (5) to the vicinity of the most protruded position.
Is configured to communicate with.

Both of the discharge ports are opened on the sides of the valve plate (9) in the minor axis direction and on both sides of the suction port (21), and the normal rotation side discharge port (22) is shown in FIG. As shown in FIG. 5, when the valve plate (9) is set to the normal position on the forward rotation side, the valve plate (9) is configured to communicate with the compression chamber (20) near the most retracted position of the piston (6) with respect to the cylinder bore (5). . On the other hand, as shown in FIG. 3, when the valve plate (9) is set at the fixed position on the reverse side, the reverse side discharge port (23) is in the vicinity of the most submerged position of the piston (6) with respect to the cylinder bore (5). Of the compression chamber (20).

The axial hole (21s) is formed in the central portion of the valve plate (9) in the major axis direction so as to be orthogonal to the suction port (21), and together with the suction port (21), the refrigerant is compressed in a compression chamber ( 20). Then, as shown in FIG. 1, when the valve plate (9) is set to the normal position on the forward rotation side, the shaft hole (21s) has the main shaft (3) on the left side, and as shown in FIG. The spindle (3) is formed so as to be located on the right side when set to the fixed position on the reverse side.

On the other hand, the upper plate (41) of the casing (4) has a second
As shown in the drawings and FIG. 4, one first opening (43) and one second opening (44) through which the refrigerant flows are formed. The both openings (43), (44) are opened in the side part of the casing (4) on the side where the piston (6) sinks into the rotor (1) to form the compression chamber (20). The valve plate (9)
When setting the forward rotation side fixed position of the first opening (43), the first opening (43)
In 1), the second opening (44) communicates with the forward rotation side discharge port (22), and conversely, when the valve plate (9) is set to the reverse rotation side fixed position, the second opening (44) sucks. The opening (21) has a first opening (43) communicating with the reverse rotation side discharge port (23).

Next, the compression operation of the swash plate compressor (c) will be described.

First, at the time of normal rotation of the rotor (1), as shown in FIG. 1, the valve plate (9) is set to the normal rotation side fixed position, and the forward rotation of the rotor (1) causes the cylinder bore (5) to move. When the piston (6) moves to the projecting stroke (expansion stroke) by the spring force of the spring (8) from the most retracted state of the piston (6), the suction port (21) communicates with the compression chamber (20) and the fluid For example, the refrigerant flows into the compression chamber (20) through the first opening (43).

Then, when the rotor (1) rotates and the cylinder bore (5) rotates near the most protruding point of the piston (6),
The compression chamber (20) is closed by the valve plate (9).

Then, as the rotor (1) rotates, the piston (6) rises in the cylinder bore (5) along the inclination of the swash plate (7), and this rise causes the fluid in the compression chamber (20) to be compressed. It

Further, when the rotation of the rotor (1) progresses and the cylinder bore (5) is rotated near the most submerged point of the piston (6), the compression chamber (20) in the cylinder bore (5) is closed by the valve plate (9). ) Of the normal rotation side discharge port (22), the normal rotation side discharge port communicates with the compression chamber (20),
It is discharged to the outside through the opening (44).

When the rotor (1) further rotates, the compression chamber (20)
, Once closed with the valve plate (9), as described above,
The suction port (21) is communicated again, and the above operation is sequentially repeated.

Next, when the rotor (1) is rotated in the reverse direction, as shown in FIG. 3, the valve plate (9) is moved in the major axis direction and set to the reverse rotation side fixed position. By the movement of the valve plate (9), the forward rotation side discharge port (22) escapes to the side of the rotor (1), and the first opening (4)
3) communicates with the compression chamber (20) via the reverse rotation side discharge port (23). That is, the suction port (21) communicates with the compression chamber (20) in the expansion stroke as in the normal rotation, and the second opening (44) communicates with the compression chamber (20) through the suction port (21). Therefore, when the rotor (1) rotates and the piston (6) is most submerged in the cylinder bore (5), the compression chamber (20) communicates with the reverse rotation side discharge port (23). Compress the fluid repeatedly. Therefore, the flow direction of the refrigerant is reversed between the forward rotation and the reverse rotation of the rotor (1),
For example, the four-way switching valve in the refrigerant circulation circuit can be omitted, the number of parts can be reduced, and the circuit can be simplified.

FIG. 5 shows another embodiment. This embodiment shows an open type swash plate compressor (c), in which a motor (M ') is provided outside the casing (4), One end of (31) is extended to the outside of the casing (4), and a motor (M ') is connected to the outer end of the main shaft (31). On the other hand, in the casing (4), a rotor (11) having a cylinder bore (5) in which a piston (6) is inserted in the main shaft (3).
And the main shaft (31) is cantilevered by the casing lower surface plate (42). Therefore, the valve plate (9) is not provided with the shaft hole (21s).

Other configurations, operations, and effects are the same as in the previous embodiment.

The application of the swash plate type compressor according to the present invention is not limited to the air conditioner for both heating and cooling, and it goes without saying that it can be widely applied to general industries.

(Effects of the Invention) As described above, according to the present invention, the valve plate having the two discharge ports is movably provided, and the flow direction of the fluid can be changed by the movement and the forward / reverse rotation of the rotor. Since the compressor itself can be provided with a four-way switching valve function, for example, the number of parts of the refrigerant circulation circuit can be reduced and the structure can be simplified.

Further, it is not necessary to support the four-way switching valve, and there is no concern about leakage of refrigerant gas or the like, which is effective.

[Brief description of drawings]

1 to 5 show an embodiment of the present invention, FIG. 1 is a horizontal sectional view of a swash plate type compressor showing the position of a valve plate at the time of normal rotation of a motor, and FIG. 2 is FIG. 3 is a horizontal sectional view showing the position of the valve plate at the time of reverse rotation of the motor, and FIG.
3 is a sectional view taken along the line BB in FIG. 3, and FIG. 5 is a central sectional view of a swash plate compressor showing another embodiment. FIG. 6 is a diagram showing a vertical cross section of a conventional swash plate compressor and a system of an air conditioner for both heating and cooling. (1), (11) …… Rotor, (3), (31) …… Spindle,
(4) …… Casing, (5) …… Cylinder bore,
(6) ... Piston, (7) ... Swash plate, (9) ... Valve plate.

Claims (2)

[Claims] 1. A rotor (1) supported in a casing (4) through a main shaft (3) so as to be able to rotate in the forward and reverse directions, and the rotor (1).
A cylinder bore (5) penetrating through the cylinder bore, and a piston (6) slidably fitted into the cylinder bore (5) to form a compression chamber (20) in the cylinder bore (5);
The piston (6) of the rotor (1) is provided on the protruding end face side of the piston (6) so as to face the end face at a predetermined interval and is inclined with respect to the end face, and the tip of the piston (6) slides and moves. The swash plate (7) and the compression chamber (20) side end surface of the rotor (1) are provided in close contact with each other, and the rotor (1)
Of the valve plate (9) which can be set and moved between the normal position on the forward side and the fixed position on the reverse side in the reverse direction. One suction port (21) communicating with the compression chamber (20) at least at the most projecting position of the piston (6) with respect to the cylinder bore (5) when both the forward rotation side fixed position and the reverse rotation side fixed position are set, and When the valve plate (9) is opened and the valve plate (9) is set to the normal position on the forward rotation side, the piston (6) with respect to the cylinder bore (5) is
Is opened in the normal rotation side discharge port (22) communicating with the compression chamber (20) and the valve plate (9) in the vicinity of the most submerged position, and when the valve plate (9) is set to the reverse rotation side fixed position, A swash plate compressor comprising: a reverse rotation side discharge port (23) communicating with a compression chamber (20) in the vicinity of the most retracted position of a piston (6) with respect to a cylinder bore (5). 2. A valve plate (9) is formed into a generally oval shape in plan view and is provided slidably in the major axis direction, and has a suction port (2) at its central portion.
1) is opened in the minor axis direction, while the forward rotation side discharge port (22) and the reverse rotation side discharge port (23) are located on both sides of the suction port (21) on one side of the short diameter direction. The swash plate compressor according to claim 1, wherein the swash plate compressor is opened.