JPH02119689A - Compressor - Google Patents

Abstract

PURPOSE:To simplify the structure and to change the discharge pressure within a wide range by letting a cooling medium flow in parallel or in a series in the first compression mechanism and the second compression mechanism disposed in a sealed receptacle. CONSTITUTION:A heat pump type refrigerating cycle includes a compressor 1. A rotary first compression mechanism 3, second compression mechanism 4 and a motor portion 5 for driving these compression mechanisms 3, 4 are accommodated in the interior of a sealed receptacle 2. When a solenoid valve 23 is closed, a cooling medium flows in parallel in the first compression mechanism 3 and the second compression mechanism 4 so that the cooling medium is compressed by one stage. When the solenoid valve 23 is opened, the cooling medium compressed by the first compression mechanism 3 is sucked in the second compression mechanism 4 and discharged from a discharge pipe 18 into the sealed receptacle. Thus, the structure can be simplified and the discharge pressure of a fluid can be changed in a wide range.

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial Application Field) The present invention relates to a compressor used in, for example, a heat pump type refrigeration cycle.

(Prior art) For example, in a heat pump type refrigeration cycle,
To improve the performance of heat pumps, high-temperature blowing, COP
It must be possible to meet various demands such as improved (operating coefficient) and rapid heating and cooling.

In order to meet such demands, the capacity of the compressor used in the heat pump type refrigeration cycle is made variable. One such method is to construct a refrigeration cycle using two compressors, a first-stage compressor and a second-stage compressor, and operate one of the compressors depending on the required capacity. Ta.

However, such a configuration requires two compressors, resulting in a complicated configuration and increased costs.

Therefore, recently, the operating speed of the compressor is controlled by a silis inverter circuit to change its capacity. However, the range in which the capacity of the compressor can be varied using the silice inverter circuit is smaller than that when changing the capacity using two compressors, a 1-stage compressor and a 2-stage compressor. There were times when I was unable to respond.

(Problem to be solved by the invention) As described above, in the past, it was not possible to change the capacity over a wide range with one compressor, so it was difficult to improve the performance of a heat pump with a simple configuration. That happened.

This invention was made based on the above circumstances, and its purpose is to provide a compressor that can be operated by switching between one-stage compression and two-stage compression with a simple configuration. There is a particular thing.

[Structure of the Invention] (Means and Effects for Solving the Problems) In order to solve the above problems, the present invention provides a pair of compression mechanisms and a motor section for driving these compression mechanisms in a closed container. In a compressor, the fluid compressed by one compression mechanism is discharged into a closed container, and the fluid compressed by the other compression mechanism is led out of the closed container by a discharge pipe to the suction side of the one compression mechanism. At the same time, the discharge pipe is provided with a check valve that allows the compressed fluid flowing through the discharge pipe to flow out into the closed container in accordance with the pressure within the closed container. This makes it possible to selectively perform one-stage compression in which fluid is passed through a pair of compression mechanisms in parallel, and two-stage compression in which fluid compressed by the other compression mechanism is further compressed by one compression mechanism. I made it.

(Example) An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 shows a heat pump type refrigeration cycle, and this refrigeration cycle is equipped with a compressor 1. This compressor 1 has an airtight container 2, and inside this airtight container 2 there is a rotary type first compressor groove 3, a second compression mechanism 4, and a motor section 5 for driving these compression mechanisms 3.4. is accommodated.

Each of the compression mechanisms 3.4 has bearings 8.9 joined to both end faces of the first and second cylinders 6.7, and a rotor 11.12 is rotatably housed inside each of them. .

A crankshaft 13 for eccentrically rotating each rotor 11 , 12 is connected to a rotor 14 of the motor section 5 . The rotor 14 is rotatably inserted into the stator 14a. Therefore, when the motor section 5 is energized and the rotor 14 is rotationally driven, each of the rotors 11.12 is eccentrically rotated within the cylinder 6.7.

Each cylinder 11.12 has a suction pipe 15.1.
．． 6 and discharge pipes 17, 18 are connected. 1st above
The suction pipe 15 connected to the cylinder 6 is connected to the outflow side of one suction cup, and the suction pipe 16 of the second cylinder 7 is connected to the outflow side of the suction cup 19 via the first check valve 21. has been done. The first check valve 21 allows fluid to flow only in the direction from one suction cup to the thin lid 7.

A discharge pipe 17 connected to the first cylinder 6 is led out of the closed container 2 and connected to one end of a bypass pipe 24 in which an intercooler 22 and a solenoid valve 23 are provided.

The other end of this bypass pipe 24 is connected to the first check valve 21
, that is, connected to the suction pipe 16 of the second cylinder 7 .

Further, a discharge pipe 17 connected to the first cylinder 6
A second check valve 2 is installed in the part located inside the airtight container 2.
5 is connected. Further, a discharge pipe 18 connected to the second cylinder 7 is opened into the closed container 2.

A main discharge pipe 26 is connected to the upper part of the closed container 2. This main discharge pipe 26 is connected to a four-way valve 27.

The four-way valve 27 is connected to the inflow side of the suction cup 19, and further connected to one end sides of an indoor heat exchanger 28 and an outdoor heat exchanger 29. These heat exchangers 2
8. The two other ends are communicated via a pressure reducing device 31.

Next, the operation of the heat pump type refrigeration cycle having the above configuration will be explained. First, when compressing a fluid refrigerant in one stage, the refrigerant circulates as shown by arrows in FIG. That is, the solenoid valve 23 is closed and the compressor 1 is operated,
When the motor section 5 is operated, the first and second compression mechanisms 3.
4 is driven, so that the refrigerant sucked into each compression mechanism 3.4 from the suction cup 19 through the suction pipe 15.16 is compressed.

Since the refrigerant compressed by the first compression mechanism 3 cannot pass through the bypass pipe 24 because the solenoid valve 23 is closed, the refrigerant is passed through the closed container 2 from the second check valve 25 provided in the discharge pipe 17. Exhale inside. Further, the refrigerant compressed by the second compression mechanism 4 is discharged from the discharge pipe 18 into the closed container 2. Then, the compressed refrigerant flows from the main discharge pipe 26 to the four-way valve 27, and during heating operation, the indoor heat exchanger 28, the pressure reducing device 31, and the outdoor heat exchanger 29.
flows in this order. Then, it flows into the suction cup 19 through the four-way valve 27, and from there flows into each of the compression mechanisms 3.
4 will be attracted.

That is, if the solenoid valve 23 is closed and the compressor 1 is operated,
Since the refrigerant flows in parallel to the first compression mechanism 3 and the second compression mechanism 4, the refrigerant is compressed in one stage.

Next, when performing two-stage compression, the refrigerant is caused to flow as indicated by the arrows in FIG. That is, the solenoid valve 23 is opened and the compressor 1 is operated. At the start of operation, the refrigerant from the suction cup 19 is drawn into the first compression mechanism 3 and the second compression mechanism 4 in parallel as shown by the broken arrow. The refrigerant sucked into the first compression mechanism 3 is compressed to a pressure P1 here, and a part of it is discharged from the second check valve 25 as shown by the dashed arrow, but most of it is discharged through the bypass pipe 24. and flows into the suction pipe 16 of the second compression mechanism 4 from a location downstream of the first check valve 21 . As a result, the pressure on the downstream side of the first check valve 21 increases more than the pressure on the upstream side, so that the low-pressure refrigerant from the suction cup 19 passes through the second check valve 21 and is transferred to the first compression mechanism 4. will no longer be attracted to. In other words, the refrigerant from the suction cup 19 is sucked only into the first compression mechanism 3.

In this way, the refrigerant compressed by the first compression mechanism 3 is transferred to the second compression mechanism 3.
is sucked into the compression mechanism 4, where the pressure P2 (
Pl > P2) and is discharged from the discharge pipe 18 into the closed container 2. When the pressure inside the closed container 2 increases due to the refrigerant discharged into the closed container 2, the pressure difference prevents the refrigerant from leaking from the second check valve 25 to the closed container 2.

Therefore, the refrigerant from one suction cup is
flows through the compression mechanism 3 and the second compression mechanism 4 in series, is pressurized to a pressure P1 by the first compression mechanism 3, and then pressurized to a higher pressure P2 by the second compression mechanism 4. , is discharged from the main discharge pipe 26 and flows to the four-way valve 27.

That is, if the solenoid valve 23 is opened and the compressor 1 is operated,
The refrigerant can be compressed in two stages by the first compression mechanism 3 and the second compression mechanism 4.

[Effects of the Invention] As described above, the present invention allows refrigerant to flow in parallel or in series through the first compression mechanism and the second compression mechanism provided in the closed container. Therefore, if the refrigerant flows in parallel, it can be compressed in one stage, and if it flows in series, it can be compressed in two stages, so the configuration can be simplified compared to the case where two compressors are used. It also has the advantage that the fluid output pressure can be varied over a wider range than in a chain in which the single-stage compressor is controlled by a silice inverter circuit.

[Brief explanation of drawings]

The drawings show one embodiment of the present invention, and Fig. 1 is a configuration diagram of a heat pump type refrigeration cycle incorporating a compressor, Fig. 2 is an explanatory diagram of the flow of refrigerant during one-stage compression, and Fig. 3 FIG. 2 is an explanatory diagram of the flow of refrigerant during two-stage compression. 2... Sealed container, 3.4... First and second compression mechanisms, 15.16... Suction pipe, 17.18... Discharge pipe,
21... First check valve, 23... Solenoid valve, 25
...Second check valve. Applicant's agent Patent attorney Takehiko Suzue

Claims (1)

[Claims] In a compressor in which a pair of compression mechanisms and a motor unit that drives these compression mechanisms are installed in a closed container, fluid compressed by one compression mechanism is discharged into the closed container, and fluid is compressed by the other compression mechanism. The compressed fluid is led out of the sealed container by the discharge pipe and introduced into the suction side of the one compression mechanism, and the compressed fluid flowing through the discharge pipe is introduced into the discharge pipe according to the pressure inside the sealed container. A compressor characterized in that it is provided with a check valve that causes the flow to flow into a closed container.