JP2020037881A5 - - Google Patents

Description

In order to achieve the above object, the compressor according to claim 1 includes a compression unit (110) that compresses and discharges a fluid, and a cover portion (120) that is arranged on the outer peripheral side of the compression unit and covers the compression unit. The cover portion is formed of a heat storage material that stores the heat generated by the compression portion, and the cover portion contains a fluid that exchanges heat with the heat storage material and conveys the heat stored in the heat storage material. A fluid flow path (120a) to be circulated is formed, and the fluid flow path is formed so that the fluid and the heat storage material are in direct contact with each other .

Further, in order to achieve the above object, the refrigerating cycle apparatus according to claim 5 is a refrigerating cycle apparatus having a compressor (11) that compresses and discharges a refrigerant.
Compressor compressing section compressing and discharging fluid (110), disposed on the outer peripheral side of the compression portion, a cover portion for covering the compression unit (120) comprises a cover portion, the compression portion is generated was being formed in the heat storage material to store heat, the cover portion, and the heat storage material and the heat exchange fluid flow path fluid Ru is a flow for transporting the heat stored in the heat storage material (120a) is formed The fluid flow path (120a) is formed so that the fluid and the heat storage material are in direct contact with each other, and is configured to be able to transfer the heat generated by the compression portion by the fluid.

As shown in FIG. 2, the compressor 11 sucks the refrigerant from the suction port 110a, a compression unit 110 that discharges from the compression to the discharge port 110b, a cover portion 120 for covering the outer peripheral side of the compression unit 110, To be equipped.

The outer peripheral surface of the second cover portion 12 2, a second connection port 122a which connects to the starting end of the fluid flow path 120a of the second cover portion 122 is formed. The first connection port 121e and the second connection port 122a are connected by a pipe 123 made of rubber or the like. An outflow port 122b connected to the end of the fluid flow path 120a of the first cover portion 121 is formed on the outer peripheral surface of the second cover portion 122.

In step S12, in a case where a reference under the following conditions frost condition (1) is satisfied, the process proceeds to step S13, open closing control unit 60b returns to the main routine by opening the on-off valve 47.

On the other hand, in the refrigeration cycle device 10 of the present embodiment, the refrigerant circuit for flowing the high-pressure refrigerant into the same heat exchanger and the refrigerant circuit for flowing the low-pressure refrigerant do not switch. That is, since it is not necessary to let the high-pressure refrigerant flow into the indoor evaporator 16 regardless of which refrigerant circuit is switched, the refrigerant circuit can be switched with a simple configuration without complicating the cycle configuration.

(6) In the heating mode, when the heating capacity of the refrigeration cycle device 10 is insufficient, the on-off valve 47 is opened to transfer the exhaust heat of the compression unit 110 stored in the cover unit 120 to the low temperature side heat medium. it may be in the form. In this embodiment, the heat absorption of the low-pressure refrigerant in the chiller 17 increases due to the temperature rise of the low-temperature side heat medium flowing through the low-temperature side heat medium circuit 30, and the high-temperature side heat medium in the water-refrigerant heat exchanger 12 increases. The amount of heat is increased, and the heating capacity of the refrigeration cycle device 10 in the heating mode is improved.

(7) the reference condition is determined in the step S 12 in FIG. 5, frost the following conditions (2), a (3).

Claims (2)

A compression unit (110) that compresses and discharges the fluid,
A cover portion (120) arranged on the outer peripheral side of the compression portion and covering the compression portion is provided.
The cover portion is formed of a heat storage material that stores the heat generated by the compression portion.
A fluid flow path (120a) is formed in the cover portion to circulate a fluid that exchanges heat with the heat storage material and conveys the heat stored in the heat storage material .
The fluid flow path is a compressor formed so that the fluid and the heat storage material are in direct contact with each other . A refrigeration cycle device having a compressor (11) that compresses and discharges a refrigerant.
The compressor
A compression unit (110) that compresses and discharges the fluid,
A cover portion (120) arranged on the outer peripheral side of the compression portion and covering the compression portion is provided.
The cover portion is formed of a heat storage material that stores the heat generated by the compression portion.
Wherein the cover portion, which is fluid flow path Ru by flowing a fluid for transporting (120a) is formed the heat stored in the heat storage material wherein the thermal storage material and by heat exchange,
The fluid flow path is formed so that the fluid and the heat storage material are in direct contact with each other.
A refrigeration cycle device configured to be able to transfer the heat generated by the compression unit by the fluid.