WO2014173181A1

WO2014173181A1 - Energy-saving compressor

Info

Publication number: WO2014173181A1
Application number: PCT/CN2014/000437
Authority: WO
Inventors: 黄小平
Original assignee: Huang Xiaoping
Priority date: 2013-04-27
Filing date: 2014-04-24
Publication date: 2014-10-30
Also published as: TW201441563A; CN104121168A

Abstract

An energy-saving compressor is a gas compressor and may be used for gas compression cooling and heating. The energy-saving compressor uses a gas cylinder provided with isothermal devices (4, 5, 6), and the isothermal devices (4, 5, 6) are formed of a recuperative exchanger and a cooling working substance. When the temperature of the cooling working substance of the isothermal devices (4, 5, 6) is equal to or lower than an air intake temperature of the compressor, the cooling working substance absorbs heat of the gas cylinder, so that the working temperature of the gas cylinder is lowered, thereby reducing energy consumption for compression of the compressor.

Description

Energy-saving compressor

The present invention relates to a gas compressor, and more particularly to a compressor cylinder provided with an isothermal heater. Background technique

Gas compressors have three compression modes, namely: variable compression, adiabatic compression and isothermal compression, of which isothermal compression is the most economical. At present, gas compressors are all operated in a multi-variable compression mode, and multi-variable compression results in high compression energy consumption due to high cylinder temperatures. Summary of the invention

The suction temperature of the compressor is generally about 15 °C, and the working temperature of the cylinder is generally between 50 °C and 65 °C, that is, the operating temperature of the general cylinder is higher than the suction temperature of 35 °C - 50 °C. . In view of the problem that the gas compressor consumes a large amount of compression energy due to the high operating temperature of the cylinder in the multi-variable compression mode, the present invention proposes a novel gas red which is provided in the cylinder of the compressor cylinder. The isothermal heater consists of a wall-mounted heat exchanger and a refrigerant. The isothermal device is installed in the cylinder of the gas rainbow (hereinafter referred to as the built-in method) or on the outer side of the cylinder (hereinafter referred to as the external method). The isothermal refrigerant is taken from the condenser outlet of the system or from the throttle outlet of the system. The outlet of the isothermal is in turn connected to the evaporator inlet of the system or the suction port of the compressor. And the isothermal refrigerant temperature is equal to or lower than the suction temperature of the compressor. During operation of the compressor, when the operating temperature of the cylinder is higher than the suction temperature, the refrigerant in the isothermal absorber absorbs the heat of the cylinder, which lowers the operating temperature of the cylinder, thereby reducing the compression energy consumption of the compressor. The temperature of the refrigerant of the isothermal unit can be adjusted as needed to optimize the energy saving effect of the compressor.

The technical solution of the present invention is:

An energy-saving compressor comprising a gas red, characterized in that: the cylinder is provided with an isothermal device, The isothermal heater is composed of a partition wall heat exchanger and a refrigerant.

Wherein: the temperature of the refrigerant of the isothermal device can be adjusted as needed.

Wherein: the temperature of the refrigerant of the isothermal device is equal to or lower than the suction temperature of the compressor. Wherein: the refrigerant of the isothermal device is taken from a condenser outlet of the system or from a throttle outlet of the system.

Wherein: the outlet of the isothermal device is connected to an evaporator inlet of the system or an intake port of the compressor.

Wherein: the isothermal device is set by an external mode or a built-in mode.

Wherein: the isothermal device is disposed on any one, any two or all three of the cylinder of the cylinder, the upper end cap of the cylinder and the lower end cap of the cylinder.

Wherein: the compressor is a rotor compressor, a reciprocating compressor, a scroll compressor, a vane compressor or a screw compressor.

Features of the invention:

1. Reduce the working temperature of the compressor and reduce the compression energy consumption of the compressor;

2. Reduce the working pressure of the cylinder, reduce the leakage loss and clearance loss of the cylinder, increase the volumetric efficiency of the compressor, and further reduce the compression energy consumption of the compressor;

3. P lowers the working temperature of the cylinder, improves the working condition of the moving parts, reduces the mechanical abrasion of the moving parts of the cylinder, and prolongs the working life of the gas rainbow;

4. Reduce the exhaust temperature of the gas rainbow, reduce the working temperature of the motor cavity of the hermetic compressor, and improve the adaptability range of the closed compressor to the high temperature environment;

5. Reduce the exhaust temperature of the compressor, make the heat load of the condenser laugh, and then reduce the heat exchange area of the condenser and reduce the production cost of the refrigeration system;

6. Improve the anti-overload capability of the compressor;

7. The isothermal device does not contain moving parts and works reliably;

8. The isothermal refrigerating working fluid is taken from the system itself, without additional consumption of other shield resources;

9. The refrigerating medium of the isothermal unit is supplied by the system itself, and no additional circulating power is needed. Device. DRAWINGS

Hereinafter, the present invention will be further described in detail by taking a rotor compressor as an example in conjunction with the drawings and specific embodiments.

Figure 1 is a cross-sectional view showing a cylinder block installation isostat of a rotor type compressor;

2 is a plan view of a cylinder block body setting isolator of a rotor type compressor;

Figure 3 is a cross-sectional view showing the isolator of the upper end cap of the rotor of the rotor type compressor;

Figure 4 is a bottom view of the upper end cap of the rotor type compressor;

Figure 5 is a cross-sectional view showing a thermostat of a lower end cap of a rotor type compressor;

Figure 6 is a bottom view of the isolator of the rotor type lower end cap of the rotor type compressor;

Figure 7 is a cross-sectional view of the air cylinder of the rotor cylinder block, the upper end cap of the cylinder, and the lower end cap of the cylinder.

Description of the reference signs:

1. Rotor type compressor cylinder block; 2. Rotor type compressor cylinder upper end cover; 3. Rotor type compressor cylinder lower end cover; 4. Isothermal device set in gas cylinder block; 5. Set on cylinder upper end cover 4. Isothermal device; 6. Isothermal device set on the lower end cap of the cylinder; 7. Cylinder suction port; 8. Compressor casing; 9. Bolt port; 10. Cylinder exhaust valve; 11. Oil drain hole; A. The isothermal inlet of the cylinder block; B. the isothermal outlet of the cylinder body; C. the isothermal inlet of the upper end cap of the gas; D. the isolator outlet of the upper end cap of the cylinder; E. The isothermal inlet of the lower end cover; F. The isothermal outlet of the lower end cover of the gas rainbow; _a . The refrigerant is cooled. detailed description

1 and 2 show an embodiment in which an isolator 4 is provided in a cylinder block 1 of a rotor compressor: the isostat 4 has a saddle shape and is a flat hollow metal cavity which is placed close to the outer side of the cylinder block 1. Forming a partition wall heat exchanger. The refrigerant A enters the isothermal chamber 4 from the inlet A. Due to the refrigerant quality a The temperature is equal to or higher than the suction temperature of the compressor, so when the working temperature of the cylinder is higher than the suction temperature, the refrigerant A absorbs the heat of the rainbow body 1 to lower the operating temperature of the cylinder, thereby causing the compressor to operate at Or close to working in isothermal compression mode, reducing the compression energy consumption of the compressor. The refrigerant a carrying the heat of the rainbow body 1 flows out of the isothermal cooler 4 from the outlet B.

3 and FIG. 4 show an embodiment in which the isolator 5 is disposed on the upper end cover 2 of the rotor of the rotor compressor: the isostat 5 is a flat hollow metal cavity, and is disposed close to the outer side of the upper end cover 2 of the cylinder to form a wall-to-wall type change. Heater. The refrigerant A enters the isothermal unit 5 from the inlet C. Since the temperature of the refrigerant A is equal to or lower than the suction temperature of the compressor, when the working temperature of the cylinder is higher than the suction temperature, the refrigerant a absorbs heat from the upper end cover 2 of the cylinder, so that the working temperature of the gas is lowered. Therefore, the compressor is operated at or close to the isothermal compression mode, so that the compression energy consumption of the compressor is reduced. The refrigerant that carries the gas upper end cap 2 heat is discharged from the outlet D to the isothermal heater 5 .

5 and 6 show an embodiment in which the isolator 6 is disposed on the lower end cover 3 of the rotor of the rotor compressor: the isostat 6 is a flat hollow metal cavity, and is disposed close to the outer side of the lower end cover 3 of the cylinder to form a wall-to-wall type change. Heater. The refrigerant A enters the isothermal chamber from the inlet E. Since the temperature of the refrigerant A is equal to or lower than the suction temperature of the compressor, when the operating temperature of the lower end cover is higher than the suction temperature, the refrigerant a absorbs heat from the lower end cover 3 of the cylinder to make the working temperature of the gas rainbow Lowering, so that the compressor operates at or near the isothermal compression mode, reducing the compression energy consumption of the compressor. Carrying the gas rainbow lower end cap 3 heat refrigerant working a out of the outlet F outflow isothermal cooler 6.

Fig. 1, Fig. 2, Fig. 3, Fig. 4, Fig. 5, and Fig. 6 respectively show the case where the isothermal chamber is separately provided in the cylinder block of the rotor type compressor, the upper end cap of the gas siphon, and the lower end cap of the cylinder.

Figure 7 shows the case where the air cylinder, the upper cylinder end cap and the lower cylinder end cap of the rotor compressor are assembled together with an isolator.

In the above embodiment, the refrigerating medium a of the isothermal unit is taken from the outlet of the condenser of the system or from the outlet of the throttle of the system through a capillary or a throttle. Generally, when the system is operating in an air conditioning state, the temperature of the refrigerant at the outlet of the condenser is 38 ° C - 42 ° C, and the temperature of the refrigerant at the outlet of the throttle is 7 ° C. -10 ° C, and the suction temperature of the compressor is generally around 15 °C. Due to The isothermal refrigerating medium a is taken from the throttle outlet of the system, which theoretically allows the compressor to operate in an isothermal compression state.

In the above embodiment, the outlet of the isothermal chamber may be connected to the evaporator inlet of the system or may be connected to the suction port of the compressor.

The above-mentioned embodiment of the intermediate temperature units 4, 5, and 6 are disposed on the outer side of the gas rainbow in an external manner, which is only for making the technical solution of the present invention more intuitive, and does not limit the setting mode of the intermediate temperature device of the present invention. In fact, the cylinder block, the upper end cap of the gas and the isolator on the lower end cap of the gas rainbow can also be built in, that is, the cylinder of the cylinder is directly processed into a partition wall heat exchanger. However, whether the isothermal device is external or built-in, it is within the scope of the claimed invention.

In the above embodiments, the description has been made by using a rotor type compressor, which is merely for making the technical solution of the present invention more intuitive, and does not limit the arrangement of the medium temperature device of the present invention. Actually, the isothermal device of the present invention can be installed on the cylinders of other types of compressors such as a reciprocating compressor, a scroll compressor, a vane compressor, and a screw compressor, and achieve the same object of the invention. The technical effects of the above-described various types of compressors described above are all within the scope of the present invention.

It should be pointed out that the technical solution of using the invention of the invention is that the temperature of the refrigerant of the isothermal unit is higher than the suction temperature of the compressor and lower than the working temperature of the cylinder of the compressor, and the same skill effect is adopted. The solution also constitutes an infringement of the invention.

Claims

Rights request

An energy-saving compressor comprising a gas rainbow, characterized in that: the gas rainbow is provided with an isothermal heater, and the isothermal heater is composed of a partition wall heat exchanger and a refrigerant.

The energy-saving compressor according to claim 1, wherein the temperature of the refrigerant of the isothermal chamber can be adjusted as needed.

The energy-saving compressor according to claim 1 or 2, characterized in that the temperature of the refrigerant of the isothermalizer is equal to or lower than the intake temperature of the compressor.

The energy-saving compressor according to claim 1 or 2, characterized in that the refrigerant of the isothermal unit is taken from a condenser outlet of the system or from a throttle outlet of the system.

The energy-saving compressor according to claim 4, wherein the outlet of the isothermal device is connected to an evaporator inlet of the system or an intake port of the compressor.

The energy-saving compressor according to claim 1, wherein the isothermal device is provided in an external manner or in a built-in manner.

The energy-saving compressor according to claim 1 or 6, wherein the isothermal device is provided in any one, any two or all of the gas red cylinder, the upper cylinder end cap and the lower cylinder end cap of the cylinder Three on.

The energy-saving compressor according to claim 1, wherein the compressor is a rotor compressor, a reciprocating compressor, a scroll compressor, a vane compressor or a screw compressor.