The present invention relates to a liquid-cooled type compressor.
In a liquid-cooled type compressor, a conventional technology for adjusting the quantity of a refrigerant injected into a compression chamber has been known. As an example of this conventional technology, there is JP-2011-516771-A (Patent Document 1)
Patent Document 1: JP 2011-516771 A
In the above-mentioned conventional technology, the pressure of the air, inside the compressor, with which the refrigerant contacts at an oil supply port is stronger as the oil supply port is closer to a delivery port of the compressor (at a higher stage). In other words, since the difference between the pressure possessed by the refrigerator and the pressure inside the compressor is smaller at a higher stage, in the case where the oil is supplied at the same pressure at a low stage and a high stage, the quantity of the refrigerant supplied is smaller at the high stage. As a result, there has been a problem that the cooling amount for cooling the air in the compression process cannot be sufficiently obtained at the high stage, and a reducing effect on compression power cannot be produced sufficiently.
In addition, in order to efficiently cool the air in the compression process by a sprayed refrigerant, the particle diameter of the refrigerant supplied should be sufficiently reduced (particulatized). However, in the case where the oil supply port diameter (or pipeline diameter) is reduced for the particulatization, fluid resistance generated at the oil supply port would be increased, resulting in a lowering in the quantity of a lubricant supplied.
In order to solve the above-mentioned problem, the present invention provides, for example, a liquid-cooled type compressor including: a liquid-cooled type compressor body; at least one first nozzle; and at least one second nozzle that is disposed on a high pressure side as compared to the first nozzle. Further, the at least one first nozzle and the at least one second nozzle each has a plurality of injection ports per nozzle and supplies a refrigerant through the injection ports into an inside of the compressor body. Furthermore, the second nozzle has the injection ports each having a diameter larger than a diameter of each of the injection ports of the first nozzle.
According to the present invention, air in the course of compression can be efficiently cooled, and compression power of a compressor can be reduced.
An air compressor (hereinafter referred in some cases to simply as “compressor”) divides a compression process into multiple stages, and a technology of reducing consumption of power for compression by cooling air in the course of compression is well known in thermodynamics. In the case where multiple compression process is divided into multiple stages, since the pressure (of air), inside the compressor, with which a lubricating oil contacts at an oil supply port differs from stage to stage of compression process, so that the difference between the pressure possessed by the lubricating oil and the pressure inside the compressor is reduced as the oil supply port is closer to a delivery port of the compressor (at a higher stage), and the amount of the lubricating oil supplied is reduced with a decrease in the differential pressure. Therefore, as the oil supply port is closer to the delivery port (higher stage), the amount of the lubricating oil supplied is reduced, and cooling amount of air during compression process is also lowered. As a result, there has been a problem in that a sufficient cooling amount of cooling the air in the compression process cannot be obtained, or a reducing effect on compression power cannot be produced sufficiently.
In order to efficiently cool the air in the compression process, the particle diameter of the lubricating oil supplied should be sufficiently reduced (particulatized). However, in the case where the oil supply port diameter (or pipeline diameter) is reduced for the particulatization, fluid resistance generated at the oil supply port would be increased, resulting in a lowering in the quantity of the lubricating oil supplied.
In view of this, the present invention provides an oil-cooled type air compression unit including: an air compressor; an oil separator that separates compressed air and a lubricating oil delivered from the air compressor; an oil cooler that cools the lubricating oil delivered from the oil separator; an after-cooler that cools the air delivered from the air compressor; an air pipeline connected such that the delivered air sequentially flows through the air compressor, the oil separator and the after-cooler; an oil circulation pipeline connected such that the lubricating oil is sequentially circulated through the air compressor, the oil separator and the oil cooler; and a blower that blows cooling air to the oil cooler and the after-cooler, the air compressor being provided with oil supply ports for supplying the lubricating oil to the air in the course of compression, the oil supply ports being provided at (N−1) stages at such positions where the compression process of the air compressor can be divided into N stages, a collision spray type nozzle being used for the oil supply ports, a motor for driving the air compressor being provided with an inverter for changing the quantity of air supplied according to a demanded air quantity by rotational speed of the motor, and a suction throttle valve for controlling the suction amount of the air compressor being provided for coping with a demanded air quantity of equal to or less than a rotational speed lower limit of the inverter. In the oil-cooled type air compression unit, the relationship between a diameter (di) of the oil supply port at i-th stage or the delivery hole whole sectional area (Ai) of the oil supply port at the i-th stage and the diameter (di+1) or the delivery hole whole sectional area (Ai+1) of the oil supply port at the (i+1)th stage is set as follows:
d
i+1
≅d
i, and Ai+1>Ai(i=1, N−1) .
Alternatively, the relationship between the collision spray angle (θi) constituting a nozzle at the oil supply port at the i-th stage and the collision spray angle (θi+1) of the nozzle at the (i+1)th stage is set as follows:
θi+1≥θi(i=1, N−1).
Further, a collision spray type nozzle with a nozzle hole diameter (d) of d≥0.5 mm is provided.
Further, where the center lines of nozzle holes of opposed collision type spray nozzles are extended in a fluid jet direction and the acute angle formed by intersection of the extended two straight lines is defined as collision spray angle, a collision spray type nozzle with collision spray angle in the range of 0°≤θ<150° is provided.
The collision spray type nozzles having such characteristics are used for the multi-stage spray oil-cooled compressor, whereby securement of the particle diameter of the oil sprayed by the nozzles and securement of the required amount of the amount of the lubricating oil supplied from an oil supply port close to the delivery port can both be realized. As a result, the air in the course of compression process can be cooled efficiently, and compression power of the compressor can be reduced.
While the oil-cooled type air compressor will be described below, it is natural that a refrigerant supplied into the compressor body may be other liquid than water and oil.
Further, the air compressor unit A includes: temperature detecting means (delivery air temperature detecting means) 30 that detects the temperature of air delivered from the air compressor 1 (the temperature of air inside the oil separator 3); temperature detecting means (outside air temperature detecting means) 31 that detects the temperature of air around the air compression unit A and the temperature of air sucked by the air compressor 1; and temperature detecting means (oil temperature detecting means) 32 that detects the temperature of the lubricating oil flowing into the bearing oil supply section 27 and the intermediate oil supply sections 26a and 26b, and the rotational speed (Nf) of the blower and the opening of the flow control valve 28 are controlled based on the temperatures detected by the temperature detecting means 30, 31 and 32.
In addition, the air compressor unit A includes: pressure detecting means 40 for detecting the pressure of air delivered from the air compressor 1; and pressure detecting means 41 for detecting the pressure of air sucked by the air compressor 1, and can control the flow rate of air delivered from the air compressor 1 according to the detected pressures.
A controller 9 of the air compressor 1 controls the rotational speed (Ncp) of the air compressor 1, the rotational speed (Nf) of the blower 6, the opening of the flow control valve 28, and the opening/closing of the three-way valve 22 and the two-way valve 15. The opening/closing of the suction throttle valve 7 is performed as follows. When the two-way valve 15 is in an open state, high-pressure air stored in the oil separator 3 flows into a connection pipe 12, a high pressure is attained at one end of the suction throttle valve 7, and a valve body of the suction throttle valve is put into a closed state. Simultaneously, the high-pressure air in the oil separator 3 is bypassed to a suction port through a connection pipe 14. Therefore, the pressure inside the oil separator 3 can be lowered. When the two-way valve 15 is in a closed state, the pressure of sucked air (atmospheric pressure) is attained at the one end of the suction throttle valve. Therefore, a pressure difference between both ends of the valve body is eliminated, the throttle valve 7 is put into an open state, and the suction air amount of the air compressor 1 is recovered.
Note that drain water generated at the after-cooler 4 is put to a draining treatment through a drain trap or the like which is not illustrated.
The two nozzle holes have a nozzle hole diameter of d, and are disposed to face each other at an angle of θ. Therefore, in the case where the lubricating oil is supplied to the spray nozzle at a certain pressure, the lubricating oil portions sprayed from the two nozzle holes collide with each other in the vicinity of a midpoint 61 of the nozzle holes at an angle of θ.
The above is a mechanism by which a particulatized lubricating oil is generated by the spray nozzle. Note that
R
d=[(dist−di)/dist]×100,
R
θ=[(θ−θst)/θst]×100,
R
p=[(dpst−dp)/dpst]×100, and
R
v=[(vt−vst)/vst]×100.
Note that dp is a spray oil diameter obtained according to variation in nozzle hole diameter (di) or collision spray angle (θ), and dpst is a reference spray oil diameter obtained from reference nozzle hole diameter (dist) and reference collision spray angle (θst). Besides, vt is a nozzle flow rate obtained according to variation in nozzle hole diameter (di) or collision spray angle (θ), and vst is a reference nozzle flow rate obtained from reference nozzle hole diameter (dist) and reference collision spray angle (θst).
From
In addition, it is seen from
Therefore, it is seen that in order to increase the flow rate while maintaining the particle diameter of the oil supplied from the collision spray nozzle, it is sufficient to enlarge the nozzle hole diameter and the collision spray angle.
For example, it is seen from
Here, as depicted in
Let nozzle root pressure be P0, let the pressure inside the compressor at the position where the nozzle is disposed be Pi, and let pressure loss generated in the spray nozzle be ΔPn(Ui), then in order to supply the oil into the compressor, the pressure loss generated in the nozzle should satisfy the relational expression of Math 1. Note that the nozzle root pressure P0 is a pressure higher than any pressure Pi in the compressor (P0>Pi). Where the relational expression of Math 1 is not satisfied, the nozzle is not able to supply the lubricating oil into the compressor. Note that Ui is the flow rate of the lubricating oil flowing in the nozzle, and the value of ΔPn is higher as the value of Ui is larger.
ΔPn(Ui)≤P0−Pi (Math 1)
Therefore, allowable pressure losses ΔPna(Uia) and ΔPnb(Uib) at the first stage and the second stage are represented as Math 2 and Math 3 using compressor internal pressures (Pia, Pib) at the first stage and the second stage.
ΔPna(Uia)≤P0−Pia (Math 2)
ΔPnb(Uib)≤P0−Pib (Math 3)
Here, since the pressure at the second stage is higher than the pressure at the first stage, that is, Pia<Pib, in the case where nozzles of the same nozzle hole diameter are applied to the first stage and the second stage, the pressure is reduced from the nozzle at the second stage by the compressor internal pressure difference ΔPi=Pib−Pia, and the quantity of the lubricating oil supplied from the nozzle at the second nozzle is smaller than the quantity of the lubricating oil supplied from the nozzle at the first stage by an amount corresponding to the differential pressure. Therefore, in order to secure the quantity of the oil supplied from the nozzle at the second stage, the pressure loss across the nozzle at the second stage should be reduced.
For this reason, the quantity of the lubricating oil flowing into the nozzle per nozzle should be reduced and the flow velocity Uib should be lowered, by enlarging the nozzle hole diameter (d2) to lower the flow velocity per nozzle, or by increasing the number of nozzles used at the first stage to enlarge the whole nozzle sectional area (A2).
In the case where the nozzle hole diameter is enlarged in order to secure the quantity of the lubricating oil supplied, the particle diameter of the oil would be enlarged and the cooling effect for the compressed air would be lowered, as has been described using
Therefore, the nozzle hole diameter is enlarged, and the collision spray angle θ2 of the oil flowing out from the nozzle is enlarged, whereby the particle diameter of the oil is prevented from being enlarged.
In
Number | Date | Country | Kind |
---|---|---|---|
2017-235688 | Dec 2017 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2018/041977 | 11/13/2018 | WO | 00 |