JPH04257671A - Compressor device - Google Patents

Abstract

PURPOSE:To provide a compressor device capable of being made small in size while keeping a heat accumulating performance and further capable of constituting an accumulator in less-expensive manner. CONSTITUTION:An accumulator constituting member 62 with its one side being released is fixed to an outer side surface 21a at a suction side of a compressing element 5 within a heat accumulating container 2. An accumulator 6 is integrally formed with the heat accumulating container 2 with this constituting member 62 and an outer side surface 21a of the heat accumulating container 2, a volume of the heat accumulating container 2 is sufficiently assured to enable a heat accumulating performance to be kept and then a clearance between the accumulator 6 and a main body 1 of the compressor is eliminated and then an entire compressing device can be made small in size and at the same time the accumulator 6 can be made in less-expensive manner.

Description

[Detailed description of the invention]

0001

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a compressor that stores heat emitted from a compressor body and utilizes this heat for defrosting operations and the like.

0002

[Prior Art] Conventionally, this type of compression device is described in Japanese Utility Model Application Laid-Open No. 63-123959, and as shown in FIG. A compression device is known in which a sealed container B is provided, a heat exchanger C for heat storage is housed in the sealed container B for heat storage, and a heat storage agent D is filled into the sealed container B for heat storage. An accumulator E is attached to the side of the compressor main body A,
An outlet pipe F of the accumulator E is connected to the compressor main body A.

0003

However, when the accumulator E is attached to the side of the heat storage sealed container B as shown in FIG. 3, the accumulator E is separated from the compressor main body A, so that the whole It becomes large in size, and the outlet pipe F connected to the accumulator E becomes long.
The passage resistance of the outlet pipe F increases accordingly, causing a problem that the compression capacity decreases.Furthermore, in order to shorten the length of the outlet pipe F, the heat storage is When a sealed container B for heat storage is formed, the heat exchanger C for heat storage stored in the sealed container B for heat storage becomes smaller and the amount of the heat storage agent D filled is also reduced, so there is a problem that heat storage performance decreases. was there.

[0004] Furthermore, there is also a conventional system in which the compressor main body A and the accumulator E are both housed in a sealed heat storage container G, as shown in FIG. However, in this case, the heat storage sealed container G becomes large in size, and the amount of heat storage agent filled into the container G also increases.

The present invention was developed in view of the above problems, and it is possible to reduce the amount of heat storage agent used, maintain the necessary heat storage performance, and downsize.
It is an object of the present invention to provide a compression device that can construct an accumulator at low cost.

[0006]

[Means for Solving the Problems] In order to achieve the above object, the present invention provides a compressor main body 1 having a compression element 5 inside.
The compressor body 1 is covered with a heat storage container 2 filled with a heat storage agent.
The compression device is configured to store heat released from the heat storage container 2, and includes an accumulator structure 62 with one side open on the suction side outer surface 21a of the compression element 5 in the heat storage container 2. Outer surface 21a of the heat storage container 2
This constitutes the accumulator 6.

[0007]

[Function] Therefore, the accumulator structure 62 with one side open is fixed to the suction side outer wall 21a of the compression element 5 in the heat storage container 2 to constitute the accumulator 6, and the heat storage container Since the outer surface 21a of 2 can be made a part of the accumulator 6,
The size of the accumulator structure 62 can be made smaller than the size of the accumulator 6 by the area utilizing the outer surface 21a, and there is no need to provide a predetermined gap between the heat storage container 2 and the accumulator 6. The accumulator 6 can be disposed integrally with the heat storage container 2, and as a result, while a sufficient volume of the heat storage container 2 can be secured and heat storage performance can be maintained, the accumulator 6 and the compressor main body can be 1, the entire compression device can be downsized, the accumulator 6 can be formed at low cost, and the amount of heat storage agent filled can be reduced compared to when the accumulator is built inside the heat storage container. The amount used can be reduced without using more than necessary. Furthermore, since the accumulator 6 is integrally arranged with the heat storage container 2, there is no need to attach the accumulator using a support.

[0008]

[Example] An example will be explained based on the drawings. The compressor shown in FIGS. 1 and 2 has a compressor main body 1 housed in a large-diameter cylindrical heat storage container 2, and an annular storage space between the compressor main body 1 and the heat storage container 2. A chamber 3 is formed, and a heat storage heat exchanger 4 is disposed in the storage chamber 3.

The compressor main body 1 includes a lid portion 12 and a body portion 1.
3. A cylindrical sealed casing 1 consisting of a bottom portion 14
A compression element 5 driven by the motor M and consisting of a cylinder 51 and a front head 52 and a rear head 53 disposed above and below the cylinder 51 is disposed inside the compressor 1. An outlet pipe 61 of an accumulator 6 disposed outside the body portion 13 of the compressor main body 1 is connected to the compression element 5.

The heat storage container 2 also includes a circular cylindrical body 21 having a larger diameter than the casing 11 of the compressor main body 1 and having an open top and bottom, and a bottom that closes the open lower end of the cylindrical body 21. It consists of a wall 22 and an annular upper lid 23 that is disposed between the cylindrical body 21 and the upper part of the casing 11 and closes the upper end opening of the storage chamber 3.
3 and the bottom wall 22, the storage chamber 3 is closed and the storage chamber 3 is filled with a heat storage agent.

Furthermore, the heat storage heat exchanger 4 includes a plurality of fins 41 arranged in an annular shape vertically oriented vertically.
... and a refrigerant pipe 42 supported in a meandering manner between the upper and lower parts of each fin 41. 41・
... are inserted and arranged so that the inner end surfaces of the fins 41 are in contact with the outer wall surface of the casing 11, and the outer end surfaces of the fins 41 are spaced apart from the inner wall surface of the heat storage container 2, The heat generated in the compressor main body 1 is transferred to each of the fins 4.
1, the heat is radiated into the storage chamber 3 and stored in the heat storage agent, and the stored heat is supplied to the indoor unit via the refrigerant pipe 42 during defrosting operation, for example. .

[0012] In the above-described compression device, an accumulator structure 62 with one side open is provided on the suction side outer surface 21a of the compression element 5 in the heat storage container 2, and the open end edge thereof is fixed to the side surface 21a,
The structure 62 and the outer surface 21a of the heat storage container 2 constitute the accumulator 6.

That is, as shown in FIG.
A vertically long concave portion 24 is formed extending from the upper end of the container 2 to the lower end thereof and recessed from a position facing each end of the heat storage heat exchanger 4 in the container 2 toward a connection position of the outlet pipe 61 of the accumulator 6. At the same time, the outlet pipe 61 is exposed to the outside from the compressor main body 1 via the heat storage container 2.
A lid-shaped accumulator structure 62 is formed, which can be completely internalized, has a size that covers the recessed part 24, has one side open, and has a vertically elongated opening 62a on the open side. By fixing the opening 62a to the suction side outer surface 21a by welding, the accumulator 6 is constituted by the suction side outer surface 21a and the accumulator structure 62. Incidentally, the accumulator structure 62 has an inlet pipe 63 at its upper end.
A baffle plate 64 is interposed between the internal opening 63a of the inlet pipe 63 and the internal opening 61a of the outlet pipe 61.

[0014] Thus, by configuring the accumulator 6 by fixing the opening 62a of the accumulator structure 62 to the suction side outer wall 21a of the compression element 5 in the heat storage container 2, the heat storage container Since the outer surface 21a of 2 can be made a part of the accumulator 6, the size of the accumulator structure 62 can be made smaller than the size of the accumulator 6 by the area using the outer surface 21a. The accumulator 6 can be disposed integrally with the heat storage container 2 without the need to provide a predetermined gap between the heat storage container 2 and the accumulator 6, and as a result, a sufficient volume of the heat storage container 2 can be secured. While the heat storage performance can be maintained, the gap between the accumulator 6 and the compressor main body 1 can be eliminated, and the entire compression device can be downsized, and the accumulator 6 can also be formed at low cost. In addition, compared to the case where the accumulator is installed inside the heat storage container as in the past, the amount of heat storage agent used can be reduced without increasing the filling amount of the heat storage agent more than necessary. Since the accumulator is arranged integrally with the accumulator 2, there is no need to attach the accumulator using a support, and the number of parts can be reduced.

[0015]

Effects of the Invention The compression device of the present invention as described above has the advantage that the compression element 5 of the heat storage container 2 has a suction side outer surface 2.
1a is provided with an accumulator structure 62 with one side open, and the accumulator 6 is constituted by the structure 62 and the outer surface 21a of the heat storage container 2. Therefore, the outer surface 21a of the heat storage container 2 is Therefore, the size of the accumulator structure 62 can be adjusted relative to the size of the accumulator 6 on the outer surface 21.
The area used for a can be reduced by the area used, and the accumulator 6 can be disposed integrally with the heat storage container 2 without the need to provide a predetermined gap between the heat storage container 2 and the accumulator 6. As a result, While the heat storage performance can be maintained by ensuring a sufficient volume of the heat storage container 2, the gap between the accumulator 6 and the compressor main body 1 can be eliminated, making it possible to downsize the entire compression device. 6 can also be formed at low cost. Also,
Compared to the conventional case where an accumulator is installed inside a heat storage container, the amount of heat storage agent used can be reduced without increasing the filling amount of the heat storage agent more than necessary. Since the accumulator is arranged and constructed in one piece, there is no need to attach the accumulator using a support, and the number of parts can also be reduced.

[Brief explanation of the drawing]

FIG. 1 is a longitudinal sectional view showing the overall structure of a compression device of the present invention.

FIG. 2 is a cross-sectional view of the compression device shown in FIG. 1, viewed from the bottom side.

FIG. 3 is an explanatory diagram showing a conventional example.

FIG. 4 is an explanatory diagram showing another conventional example.

[Explanation of symbols]

1 Compressor body 2 Heat storage container 21a　Suction side outer surface 5 Compression element 6 Accumulator 62 Accumulator structure

Claims (1)

[Claims] 1. A compression device in which a compressor body 1 containing a compression element 5 is covered with a heat storage container 2 filled with a heat storage agent to store heat released from the compressor body 1, comprising:
An accumulator structure 62 with one side open is provided on the suction side outer surface 21a of the compression element 5 in the heat storage container 2, and the accumulator 6 is configured by the structure 62 and the outer surface 21a of the heat storage container 2. A compression device characterized by: