KR20140029262A - Power generation apparatus and control method thereof - Google Patents

Abstract

The present invention relates to a generating device comprising an evaporator to evaporate an operating medium; an inflator to inflate the operating medium; an oil separator to separate lubricating oil discharged with the operating medium from the inflator; a condenser to condense the operating medium; a circulation passage where an operating medium pump, which is delivering the operating medium condensed at the condenser, is connected in series; a generator driven by having the operating medium be inflated in the inflator; a lubricating oil pump delivering lubricating oil in the oil separator to the inflator; a temperature sensor sensing the temperature of the lubricating oil in the oil separator; a control means to perform driving control to drive the lubricating oil pump, and then driving the operating medium pump when a temperature sensed by the temperature sensor becomes a particular value.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a power generation apparatus,

The present invention relates to a power generation device and a control method thereof.

2. Description of the Related Art Generally, a power generation apparatus that recovers an array from various facilities such as factories and performs power generation using the energy of the recovered array is known. Among such power generation devices, a binary power generation device, that is, a power generation device using a Rankine cycle using a low-boiling working medium for driving the expander is disclosed in Japanese Patent Application Laid-Open No. 2003-161114. The generator includes an evaporator for evaporating the working medium, an expander for expanding the working medium, an oil separator for separating the lubricating oil discharged together with the working medium from the expander, a condenser for condensing the working medium, A lubricating oil pump for sending the lubricating oil in the oil separator to the inflator, and a lubricating oil pump for circulating the lubricating oil in the oil separator to the inflator, Respectively.

Generally, the temperature of the lubricating oil stored in the oil separator is low before starting the power generation apparatus, and therefore the viscosity of the lubricating oil is high. Thereby, when the lubricant pump and the working medium pump are driven in this state, a sufficient amount of lubricant may not be supplied to the bearing portion of the inflator so that the inflator is smoothly driven. In this case, there is a possibility that problems such as the occurrence of sealing in the bearing portion of the inflator may occur.

Since the power generation device of the invention disclosed in the patent publication does not describe the starting method at all, when the power generation device is started as it is, problems such as the occurrence of seizing in the bearing portion of the inflator I am concerned.

An object of the present invention is to prevent squeezing of an inflator at the time of starting a power generating apparatus.

As a means for solving the above-mentioned problems, the present invention relates to an oil separator for separating a lubricating oil discharged from the inflator together with the working medium from an evaporator for evaporating the working medium, an expander for expanding the working medium, A circulating flow passage in which a working medium pump for sending a working medium condensed in the condenser to the evaporator is connected in series; a generator driven by expansion of the working medium in the inflator; A lubricating oil pump for sending lubricating oil to the inflator; a temperature sensor for detecting a temperature of the lubricating oil in the oil separator; and a controller for driving the lubricating oil pump, and thereafter, when the temperature detected by the temperature sensor reaches a predetermined value, And control means for performing start control for driving the medium pump Power generation device.

According to the power generation apparatus of the present invention, it is possible to prevent the inflator from being squeezed at the time of startup. Specifically, when the temperature detected by the temperature sensor reaches a predetermined value, that is, when a sufficient amount of lubricating oil is supplied to the expander When the viscosity of the lubricating oil is lowered to such an extent that the lubricating oil is supplied to the lubricating oil supply port. Therefore, when the inflator is driven by the working medium circulating in the circulating flow path by driving the working medium pump, a sufficient amount of lubricating oil is supplied to the inflator so that the inflator is smoothly driven, Can be prevented.

Further, the temperature of the lubricating oil in the oil separator rises sufficiently by the heat of the lubricating oil pump at the time of driving the lubricating oil pump.

In this case, it is preferable to further include a heating means for heating the lubricating oil in the oil separator, and the control means controls, in the starting control, driving the heating means simultaneously with or after the driving of the lubricating oil pump .

In this way, the time until the temperature of the lubricating oil detected by the temperature sensor reaches the predetermined value can be shortened.

Further, in the present invention, in the start control, the control means controls the start-up control so that, as the temperature detected by the temperature sensor rises from when the temperature detected by the temperature sensor becomes the first value as the predetermined value The operating medium pump is driven at a constant rotational speed for a predetermined period of time by gradually increasing the rotational speed of the working medium pump, and after the elapse of the predetermined time, Wherein the speed of rotation of the working medium pump is set to be higher than the constant speed of rotation when the temperature detected by the temperature sensor becomes a second value higher than the first value, Control may be performed by driving at two revolutions.

By doing so, the power generation amount can be efficiently increased while preventing the inflator from being seized, and the normal operation of the power generation apparatus can be started. Specifically, in the start control, the control means controls the start-up control so that, as the temperature detected by the temperature sensor rises from when the temperature detected by the temperature sensor becomes the first value as the predetermined value, Since the control is performed such that the rotational speed of the pump is gradually increased until the rotational speed reaches the constant rotational speed and the operating medium pump is driven at the constant rotational speed for a predetermined time after the rotational speed of the working medium pump reaches the constant rotational speed, An amount of power generation corresponding to the number of revolutions of the working medium pump is obtained from the generator. At this time, since the inflator is supplied with a sufficient amount of lubricating oil, the inflation of the inflator does not occur. Further, since the time for rotating at the constant rotation speed is maintained for a predetermined time, the system of the present apparatus is stabilized. Thereafter, the control means gradually raises the rotational speed of the working medium pump from the constant rotational speed with the rise of the temperature detected by the temperature sensor, and the temperature sensed by the temperature sensor reaches the first The control means controls the drive of the working medium pump by the second rotation speed which is higher than the constant rotation speed of the working medium pump. The second power generation amount larger than the power generation amount obtained from the generator when the working medium pump is rotating at the constant speed is smaller than the second power generation amount when the working medium pump is rotating at the constant speed, Lt; / RTI > Therefore, it is possible to effectively increase the amount of power generation while shifting the inflator to the normal state, thereby shifting to the normal operation of the power generation device.

Alternatively, in the start control, the control means controls the rotation speed of the working medium pump to the first rotation speed until the temperature detected by the temperature sensor becomes a second value higher than the first value as the predetermined value And when the temperature detected by the temperature sensor reaches the second value, control may be performed to drive the rotational speed of the working medium pump at a second rotational speed that is larger than the first rotational speed.

Even in this way, it is possible to increase the amount of power generation efficiently while shifting to the normal operation of the power generation apparatus while preventing the inflator from being seized. Specifically, when the temperature detected by the temperature sensor reaches a first value as a predetermined value in the start control, the control means performs control to drive the working medium pump at the first rotation speed, The first power generation amount corresponding to the flow rate of the working medium circulated by the driving of the working medium pump by the first number of revolutions, that is, the driving force for driving the inflator, is obtained from the generator. At this time, since the inflator is supplied with a sufficient amount of lubricating oil, the inflation of the inflator does not occur. When the temperature detected by the temperature sensor reaches a second value higher than the first value, the control means controls the rotation speed of the working medium pump to be higher than the first rotation speed The flow rate of the working medium circulated by driving of the working medium pump by the second number of revolutions, that is, the amount of electricity generated by the working medium in accordance with the driving force for driving the inflator And a second power generation amount larger than the first power generation amount is obtained from the generator. Therefore, it is possible to effectively increase the amount of power generation while shifting the inflator to the normal state, thereby shifting to the normal operation of the power generation device.

In this case, it is preferable to further include a bypass flow path connecting the flow path between the inflator and the evaporator, the flow path between the inflator and the oil separator, and the bypass valve provided in the bypass flow path, The bypass valve is opened while the working medium pump is being driven by the first rotational speed and the bypass valve is closed while the working medium pump is being driven by the second rotational speed in the startup control, It is preferable to perform control.

In this way, the temperature of the lubricating oil can be raised to the second value prematurely while preventing the inflator from being squeezed. Specifically, while the working medium pump is being driven by the first rotational speed, that is, until the temperature of the lubricating oil detected by the temperature sensor reaches the second value, the bypass valve is opened Therefore, a part of the working medium circulating in the circulating flow passage joins the lubricating oil after being discharged from the inflator and flowing into the oil separator via the bypass passage without passing through the inflator. Here, since the temperature of the working medium is lowered by passing through the inflator, the temperature of the lubricating oil that has passed through the inflator together with the working medium is lowered. However, the temperature of the working medium hardly drops when the inflator does not pass the inflator Do not. Therefore, by providing the bypass flow path, the lubricant before being introduced into the oil separator after being discharged from the inflator and having a temperature substantially equal to that of the working medium before being introduced into the inflator, that is, the operation after passing through the inflator The working medium having a temperature higher than the medium can be joined. As a result, the temperature of the lubricating oil rises to the second value prematurely.

Further, while the bypass valve is opened, a part of the working medium passes through the bypass flow path, so that only a part of the working medium circulating in the circulation flow path does not pass through the inflator. That is, the driving force for driving the inflator is not increased as compared with the case where the bypass flow path is not provided, so that the inflation of the inflator is easily prevented.

According to the present invention, there is provided a control method for a power generation device, comprising: an evaporator for evaporating a working medium; an expander for expanding the working medium; an oil separating lubricant discharged from the expander, A condenser for condensing the working medium, a circulation flow passage in which a working medium pump for sending the working medium condensed in the condenser to the evaporator is connected in series, a generator driven by expansion of the working medium in the inflator, A lubricating oil pump driving step of driving the lubricating oil pump, the lubricating oil pump including a lubricating oil pump for sending lubricating oil in the oil separator to the inflator, and a temperature sensor for detecting the temperature of the lubricating oil in the oil separator, When the temperature reaches a predetermined value, It provides a control method for a power generator comprising a copper medium pump drive step.

According to the control method of the present invention, it is possible to prevent the inflator from being squeezed at the time of starting the power generating device. Specifically, the control method includes: a lubricating oil pump drive step of driving the lubricating oil pump; a lubricating oil pump drive step of driving the lubricating oil pump when the temperature detected by the temperature sensor reaches a predetermined value, that is, And an operating medium pump driving step of driving the working medium pump when the viscosity of the lubricating oil has dropped to such an extent that the lubricating oil is supplied to the expander. Therefore, when the inflator is driven by the working medium circulating in the circulating flow path by driving the working medium pump, a sufficient amount of lubricating oil is supplied to the inflator so that the inflator is smoothly driven, Can be prevented.

In this case, in the operating medium pump driving step, as the temperature detected by the temperature sensor rises from when the temperature detected by the temperature sensor becomes the first value as the predetermined value, Wherein the control unit controls the operating medium pump so that the operating medium pump is driven at a constant speed for a predetermined period of time by increasing the number of revolutions of the operating medium pump, When the temperature detected by the temperature sensor reaches a second value higher than the first value, the rotational speed of the working medium pump is driven by the second rotational speed that is larger than the constant rotational speed, .

By doing so, the power generation amount can be efficiently increased while preventing the inflator from being seized, and the normal operation of the power generation apparatus can be started. Specifically, in the operating medium pump driving step, as the temperature detected by the temperature sensor rises from when the temperature detected by the temperature sensor reaches the first value as the predetermined value, the rotation of the working medium pump Since the number of revolutions of the working medium pump is gradually increased until the speed of the working medium pump reaches the constant speed, and the working medium pump is driven at the constant speed for the predetermined time after the speed of the working medium pump reaches the constant speed, The amount of generated power is obtained from the generator. At this time, since the inflator is supplied with a sufficient amount of lubricating oil, the inflation of the inflator does not occur. Further, since the time for rotating at the constant rotation speed is maintained for a predetermined time, the system of the present apparatus is stabilized. Thereafter, the rotation speed of the working medium pump is gradually increased from the constant speed rotation speed with the rise of the temperature detected by the temperature sensor, and the temperature detected by the temperature sensor is gradually increased from the second , The flow rate of the working medium circulated by the driving of the working medium pump by the second rotating speed, that is, the flow rate of the working medium circulated by the second working fluid, A second power generation amount that is larger than a power generation amount obtained from the generator when the working medium pump is rotating at the constant speed is obtained from the power generator, the power generation amount corresponding to the driving force for driving the inflator. Therefore, it is possible to effectively increase the amount of power generation while shifting the inflator to the normal state, thereby shifting to the normal operation of the power generation device. Alternatively, in the operation medium pump driving step, until the temperature detected by the temperature sensor becomes a second value higher than the first value as the predetermined value, the rotation number of the working medium pump is driven by the first rotation number And when the temperature detected by the temperature sensor reaches the second value, the rotational speed of the working medium pump may be driven by the second rotational speed which is larger than the first rotational speed.

Even in this way, it is possible to increase the amount of power generation efficiently while shifting to the normal operation of the power generation apparatus while preventing the inflator from being seized. Specifically, in the operating medium pump driving step, when the temperature detected by the temperature sensor reaches a first value as a predetermined value, the operating medium pump is driven by the first rotating speed. Therefore, The first power generation amount corresponding to the flow rate of the working medium circulated by the drive of the medium pump, that is, the driving force for driving the inflator, is obtained from the generator. At this time, since the inflator is supplied with a sufficient amount of lubricating oil, the inflation of the inflator does not occur. In this operation medium pump driving step, when the temperature detected by the temperature sensor becomes a second value higher than the first value, the rotation number of the working medium pump is changed to the second rotation The flow rate of the working medium circulated by the driving of the working medium pump by the second number of revolutions, that is, the amount of power generation corresponding to the driving force by which the working medium drives the inflator, A large second generation amount is obtained from the generator. Therefore, it is possible to effectively increase the amount of power generation while shifting the inflator to the normal state, thereby shifting to the normal operation of the power generation device.

In this case, the power generation apparatus may further include a bypass flow path connecting the flow path between the inflator and the evaporator, the flow path between the inflator and the oil separator, and the bypass valve provided in the bypass flow path , The bypass valve is opened while the working medium pump is being driven by the first rotation speed in the working medium pump driving step, and while the working medium pump is being driven by the second rotation speed, It is desirable to close the valve.

In this way, the temperature of the lubricating oil can be raised to the second value prematurely while preventing the inflator from being squeezed. Specifically, while the working medium pump is driven by the first rotational speed, that is, until the temperature of the lubricating oil detected by the temperature sensor reaches the second value, the bypass valve is opened So that a part of the working medium circulating in the circulating flow passage joins the lubricating oil before being introduced into the oil separator after being discharged from the inflator via the bypass flow passage without passing through the inflator. Here, since the temperature of the working medium is lowered by passing through the inflator, the temperature of the lubricating oil that has passed through the inflator together with the working medium is lowered. However, the temperature of the working medium hardly drops when the inflator does not pass the inflator Do not. Therefore, by providing the bypass flow path, the lubricant before being introduced into the oil separator after being discharged from the inflator and having a temperature substantially equal to that of the working medium before being introduced into the inflator, that is, the operation after passing through the inflator The working medium having a temperature higher than the medium can be joined. As a result, the temperature of the lubricating oil rises to the second value prematurely.

Further, while the bypass valve is opened, a part of the working medium passes through the bypass flow path, so that only a part of the working medium circulating in the circulation flow path does not pass through the inflator. That is, the driving force for driving the inflator is not increased as compared with the case where the bypass flow path is not provided, so that the inflation of the inflator is easily prevented.

INDUSTRIAL APPLICABILITY As described above, according to the present invention, it is possible to prevent squeezing of the inflator at the time of starting the power generation device.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a view schematically showing a configuration of a power generating apparatus according to a first embodiment of the present invention. Fig.
2 is a flow chart for explaining a control operation at the time of starting the power generation apparatus;
3 is a graph showing control contents of the number of revolutions of the working medium pump according to the second embodiment of the present invention.
4 is a graph showing a modified example of the control contents of the number of revolutions of the working medium pump of the second embodiment.

(1st embodiment)

A power generating apparatus and a control method thereof according to a first embodiment of the present invention will be described with reference to Figs. 1 and 2. Fig.

Fig. 1 shows a configuration of a power generation apparatus of the present embodiment. Specifically, the power generation apparatus includes a circulation flow path 10 in which the working medium circulates, a generator 20, an oil flow path 30 through which the lubricating oil circulates, a lubricating oil pump 31, And a control means 50 for performing various controls. The power generation apparatus is preferably provided with a heating means 33, a bypass flow path 40, and a bypass valve V2 provided in the bypass flow path. Further, a working medium (for example, HFC245fa) having a boiling point lower than that of water circulates in the circulating flow path 10.

The circulating flow path 10 includes an evaporator 11 for evaporating the working medium, an expander 12 for expanding the working medium, an oil separator 13 for separating the lubricating oil discharged together with the working medium from the expander 12, A condenser 14 for condensing the working medium and a working medium pump 15 for sending the working medium condensed in the condenser 14 to the evaporator 11 are connected in series. The circulating flow path 10 is provided with a shielding valve V1. Only when the shielding valve V1 is open, the working medium can circulate through the circulating flow path 10. [

The evaporator (11) evaporates the liquid working medium into saturated steam or superheated steam. The evaporator 11 has a working medium flow path 11a through which the working medium flows and a heating medium flow path 11b through which the heating medium flows by being connected to the flow path 16 through which the heating medium supplied from the external heat source flows. The working medium flowing through the working medium flow path 11a evaporates by heat exchange with the heating medium flowing through the heating medium flow path 11b. Examples of the heating medium flowing through the flow path 16 include steam generated from a borehole (steam column), steam generated from a factory or the like, steam generated by a collector using solar heat as a heat source, biomass or fossil fuel And steam generated from a boiler using the steam as a heat source.

The inflator 12 is provided on the downstream side of the evaporator 11 in the circulation flow path 10 and expands the working medium evaporated in the evaporator 11 to extract kinetic energy from the working medium. In the present embodiment, a screw expander is used as the inflator 12. The screw expander has a pair of female and male screw rotors (not shown) housed in a rotor chamber (not shown) formed in the casing of the inflator. In this screw expander, the screw rotor is rotated by an expansion force of a working medium supplied from the inlet port formed in the casing to the rotor chamber. Then, the working medium whose pressure is reduced due to expansion in the rotor chamber is discharged from the discharge port formed in the casing.

The oil separator 13 is provided between the expansion device 12 and the condenser 14 in the circulation flow path 10. The oil separator 13 separates the lubricating oil from the mixed fluid of the working medium and the lubricating oil discharged from the inflator 12 and stores the separated lubricating oil in the oil separator 13.

The condenser 14 condenses the gaseous working medium into a liquid working medium. The condenser 14 is provided on the downstream side of the oil separator 13 in the circulation flow passage 10 and the gas-phase working medium discharged from the oil separator 13 to the circulation flow passage 10 is introduced. The condenser 14 has a working medium flow path 14a through which a gaseous working medium flows and a cooling medium flow path 14b through which the cooling medium flows by being connected to a flow path 17 through which a cooling medium supplied from the outside flows. The working medium flowing through the working medium flow path 14a is condensed by heat exchange with the cooling medium flowing through the cooling medium flow path 14b. As the cooling medium flowing through the flow path 17, for example, cooling water recirculating in a cooling tower can be mentioned.

The working medium pump 15 is provided on the downstream side of the condenser 14 (between the evaporator 11 and the condenser 14) in the circulating flow path 10, and the working medium is circulated in the circulating flow path 10 To circulate. The working medium pump 15 pressurizes the liquid working medium condensed in the condenser 14 to a predetermined pressure and sends it to the evaporator 11. [ As the working medium pump 15, a centrifugal pump having an impeller as a rotor or a gear pump comprising a pair of gears with a rotor is used. This working medium pump 15 can be driven at an arbitrary number of revolutions.

The generator 20 is connected to the inflator 12 and is driven by expanding the working medium in the inflator 12 and driving the screw rotor. In the present embodiment, an IPM generator (permanent magnet synchronous generator) is used as the generator 20. Specifically, the IPM generator has a rotary shaft connected to one of the pair of screw rotors of the inflator 12, and the rotary shaft is rotated by the rotation of the screw rotor to generate electric power.

1, the oil passage 30 is a passage for supplying the lubricating oil stored in the oil separator 13 to the inflator 12 again, that is, a passage through which the lubricating oil flows. The lubricating oil supplied to the expander 12 functions as a seal member for sealing between the screw rotor and between the screw rotor and the rotor chamber. Thus, the lowering of the expansion efficiency of the working medium is suppressed.

The lubricant pump 31 is provided between the oil separator 13 and the inflator 12 in the oil passage 30 and is for sending the lubricant stored in the oil separator 13 to the inflator 12 .

The temperature sensor 32 detects the temperature of the lubricating oil stored in the oil separator 13.

The heating means 33 heats the lubricating oil stored in the oil separator 13. In this embodiment, as the heating means 33, a heater that is immersed in lubricating oil is used. However, the heater is not limited to the one immersed in the lubricating oil, but may be of the type surrounding the oil separator 13.

The bypass flow path 40 is a flow path between the inflator 12 and the evaporator 11 in the circulation flow path 10 and between the inflator 12 and the oil separator 13 in the circulation flow path 10, Respectively. That is, one end of the bypass passage 40 is connected to the flow path between the evaporator 11 and the inflator 12 in the circulation flow passage 10, and the other end is connected to the inflow- (12) and the oil separator (13). The bypass valve 40 is provided with a bypass valve V2. Only when the bypass valve V2 is open, the working medium can flow through the bypass flow path 40. [

The control means 50 includes a ROM, a RAM, a storage medium, a CPU, and the like, and performs a predetermined function by executing a program stored in a ROM, a RAM, or a storage medium. The various controls performed by the control means 50 include start control for starting the power generation device. The control means 50 includes a heating control portion 51 for starting and stopping the heating means 33, a lubricating oil pump control portion 52 for driving the lubricating oil pump 31, A working medium pump control section 53 for driving the working medium pump 15 at a predetermined number of revolutions Rp1 or Rp2 in accordance with the temperature T detected by the sensor 32, A generator control section 54 for driving the generator 20 at a predetermined revolution number Rd1 or Rd2 in accordance with the control signal Vr1, a shielding valve control section 55 for controlling the opening and closing of the shielding valve V1, a bypass valve V2 And a bypass valve control unit 56 for controlling the opening and closing of the bypass valve.

The shielding valve control unit 55 opens the shielding valve V1 when the value T detected by the temperature sensor 32 reaches the first value T1.

The working medium pump control section 53 drives the working medium pump 15 to the first rotation speed Rp1 and drives the working medium pump 15 to the temperature sensor 32 when the value T detected by the temperature sensor 32 reaches the first value T1. The operation medium pump 15 is driven to the second rotation speed Rp2 which is a rotation speed higher than the first rotation speed Rp1 when the value T detected by the first rotation speed sensor 14 becomes the second value T2 (preset value) . The first value T1 is a predetermined value as a temperature at which the viscosity of the lubricant is lowered so that a sufficient amount of lubricating oil is supplied to the inflator 12 so that the inflator 12 is smoothly driven.

The generator control unit 54 adjusts the number of revolutions so that the number of revolutions of the generator 20 becomes the first number of revolutions Rd1 when the value T detected by the temperature sensor 32 reaches the first value T1, When the value T detected by the generator 20 becomes the second value T2 which is larger than the first value T1, the rotation speed of the generator 20 is reduced to the second rotation speed Rd2, which is the rotation speed greater than the first rotation speed Rd1 .

The bypass valve control unit 56 opens the bypass valve V2 when the value T detected by the temperature sensor 32 reaches the first value T1, When the second value T2 becomes larger than the first value T1, the bypass valve V2 is closed.

The heating control section 51 stops driving the heating means 33 when the value T detected by the temperature sensor 32 reaches the second value T2 which is larger than the first value T1.

Next, the start-up control of the control means 50 will be described with reference to Fig. The start control includes a lubricating oil pump driving step and a working medium pump driving step. The lubricating oil pump driving step means the following step ST2, and the working medium pump driving step means the following steps ST3 to ST12.

The control means 50 turns on the heating means 33 (step ST1) and drives the lubricating oil pump 31 (step ST2) when receiving the start command of the power generation apparatus ). Thereby, the lubricating oil stored in the oil separator 13 flows so as to circulate in the order of the oil passage 30, the inflator 12, and the oil separator 13. At this time, since the lubricating oil stored in the oil separator 13 is heated by the heating of the heating means 33 and the heat generated by the lubricating oil pump 31 at the time of driving the lubricating oil pump 31, . Also, these steps ST1 and ST2 may be executed first, or may be executed at the same time. Further, since the lubricating oil stored in the oil separator 13 is sufficiently heated by the heat of the lubricating oil pump 31, the step ST1 may be omitted. In this case, the heating means 33 is omitted.

When the detection temperature T of the temperature sensor 32 reaches the first value T1 (step ST3), the bypass valve V2 is opened (step ST4), the shielding valve V1 is opened (step ST5 ), And drives the working medium pump 15 at the first rotation speed Rp1 (step ST6). Thereby, the working medium flows through the circulation flow path 10 and the bypass flow path 40. [ At this time, by adjusting the rotational speed of the generator 20 to the first rotational speed Rd1 (step ST7), the first power generation amount is obtained from the generator 20. Specifically, a part of the working medium in the gaseous state via the evaporator 11 is directed toward the inflator 12, and the rest is directed to the bypass flow path 40. The working medium flowing into the expander (12) is expanded and discharged from the expander (12) after the temperature and pressure are lowered by rotating the screw rotor. The first power generation amount is obtained from the generator 20 by rotating the rotation axis of the generator 20 at the first rotation speed Rd1 to correspond to the rotation speed of the screw rotor at this time. In other words, the flow rate of the working medium flowing into the inflator 12 by the driving of the working medium pump 15 by the first rotation speed Rp1, that is, the flow rate of the working medium flowing into the inflator 12 The first power generation amount is obtained from the generator 20. On the other hand, the working medium flowing into the bypass flow path 40 flows into the bypass flow path 40 at the downstream side of the inflator 12 in a state substantially equal to the temperature and pressure of the working medium before flowing into the bypass path 40 12 and the lubricating oil. These steps ST4 to ST7 may be executed in any order or all at the same time. Further, the bypass flow path 40 and the bypass valve V2 may be omitted.

Thereafter, when the detected temperature T by the temperature sensor 32 becomes the second value T2 (step ST8) which is larger than the first value T1, the heating means 33 is turned off (step ST9) 15) is driven by the second rotation speed Rp2 which is higher than the first rotation speed Rp1 (step ST10), and the bypass valve V2 is closed (step ST12). As a result, the amount of the working medium flowing into the inflator 12 is increased. At this time, the rotational speed of the generator 20 is adjusted to the second rotational speed Rd2 that is greater than the first rotational speed Rd1 (step ST11), so that the generator 20 obtains a second power generation amount larger than the first power generation amount Loses. More specifically, since the bypass valve V2 is closed, the working medium flows only through the circulating flow path 10 without flowing through the bypass flow path 40, The amount of the working medium flowing into the inflator 12 is greatly increased since the second rotation speed Rp2 is higher than the rotation speed Rp1. As a result, the rotation of the screw rotor of the inflator 12 is also increased. By rotating the rotary shaft of the generator 20 at the second rotation speed Rd2 so as to correspond to the number of rotations of the screw rotor at this time, a second power generation amount larger than the first power generation amount can be obtained from the generator 20. In other words, the flow rate of the working medium flowing into the inflator 12 by the drive of the working medium pump 15 by the second rotation speed Rp2, that is, the flow rate of the working medium flowing into the inflator 12 And a second power generation amount is obtained from the generator 20. These steps ST9 to ST12 may be executed in any order or all at the same time.

As described above, according to the power generation apparatus of the present embodiment, it is possible to prevent the inflator 12 from being squeezed at the time of starting. Specifically, when the temperature T detected by the temperature sensor 32 reaches the first value T1, that is, when the inflator 12 is at the first value T1, the control means 50 drives the lubricating oil pump 31, The start control for driving the working medium pump 15 is carried out when the viscosity of the lubricating oil is reduced to such an extent that a sufficient amount of lubricating oil is supplied to the expander 12. [ Therefore, when the inflator 12 is driven by the working medium circulating through the circulating flow path 10 by the operation of the working medium pump 15, a sufficient amount of lubricating oil is supplied to the inflator 12 so that the inflator 12 can be smoothly driven. Is supplied to the expander (12), so that the expansion of the expander (12) can be prevented.

The power generation apparatus of the present embodiment is provided with the heating means 33. The control means 50 performs control for starting the heating means 33 substantially simultaneously with the driving of the lubricating oil pump 31 It is possible to shorten the time until the temperature T of the lubricating oil detected by the temperature sensor 32 reaches the first value T1. However, the start-up of the heating means 33 need not be exactly the same as the start-up of the lubricating oil pump 31 but may be slightly before or after the start of the lubricating oil pump 31.

In the present embodiment, in the start control, until the temperature T detected by the temperature sensor 32 becomes the second value T2 higher than the first value T1, the control means 50 controls the operation medium pump 15 is driven by the first rotation speed Rp1 and the temperature T detected by the temperature sensor 32 reaches the second value T2, the rotation speed of the working medium pump 15 is set to the first rotation speed Rp1 The second rotation speed Rp2 that is greater than the second rotation speed Rp2. That is, the control means 50 rotates the working medium pump 15 to the first rotation speed Rp1 at a relatively low speed (when the temperature T detected by the temperature sensor 32 becomes the second value T2) (The number of revolutions of the rotary shaft of the generator 20) is not excessively increased, and when the temperature T becomes the second value T2 (when the viscosity of the lubricant is sufficiently lowered), the operation The rotation speed of the screw rotor (the rotation speed of the rotation shaft of the generator 20) is raised by rotating (high-speed rotation) the medium pump 15 at a second rotation speed Rp2 greater than the first rotation speed Rp1. Therefore, while the expansion device 12 is prevented from being seized, the power generation amount can be efficiently increased, and the normal operation of the power generation device can be started.

The power generation apparatus of the present embodiment is provided with the bypass flow passage 40 and the bypass valve V2 and the control means 50 controls the operation of the working medium pump 15 in the first rotation The bypass valve V2 is opened and the bypass valve V2 is closed while the working medium pump 15 is being driven at the second rotation speed Rp2 while being driven with the number Rp1, 12, the temperature T of the lubricating oil can be raised to the second value T2 early. Specifically, while the working medium pump 15 is being driven at the first rotation speed Rp1, that is, until the temperature T of the lubricating oil detected by the temperature sensor 32 reaches the second value T2, A part of the working medium circulating through the circulating flow path 10 is discharged from the inflator 12 via the bypass flow path 40 without passing through the inflator 12 because the bypass valve V2 is opened. And joins the lubricant before entering the oil separator 13. Here, since the temperature of the working medium is lowered by passing through the inflator 12, the temperature of the lubricating oil that has passed through the inflator 12 together with the working medium also decreases. However, When not used, it hardly decreases. Therefore, by providing the bypass flow passage 40, the lubricating oil after being discharged from the inflator 12 and before being introduced into the oil separator 13 has substantially the same temperature as that of the working medium before being introduced into the inflator 12 , It is possible to join the working medium having a temperature higher than that of the working medium after passing through the inflator (12). Thereby, the temperature of the lubricating oil rises to the second value T2 in an early stage.

While the bypass valve V2 is opened, part of the working medium passes through the bypass flow path 40, so that only a part of the working medium circulating through the circulation flow path 10 does not pass through the inflator 12 . In other words, the rotation of the screw rotor of the inflator 12 is not increased as compared with the case where the bypass flow path 40 is not provided, so the sealing of the inflator 12 is easily prevented.

(Second Embodiment)

3 is a graph showing control contents of the number of revolutions of the working medium pump according to the second embodiment of the present invention. In this graph, the point of intersection with the ordinate of the abscissa is the time when the value T detected by the temperature sensor 32 becomes the first value T1. In the second embodiment, only the parts different from those of the first embodiment are described, and the description of the same structure, operation, and effect as those of the first embodiment is omitted. In this embodiment, the same components as those in the first embodiment are denoted by the same reference numerals.

As shown in FIG. 3, when the value T detected by the temperature sensor 32 reaches the first value T1, the working medium pump control section 53 of the working medium pump control section 53 of the working medium P The rotational speed of the pump 15 is gradually increased until the rotational speed reaches the constant rotational speed Rp3 and the rotational speed of the working medium pump 15 reaches the constant rotational speed Rp3 for a predetermined period of time The operating medium pump 15 is driven at the constant speed Rp3. After the elapse of the predetermined time, the rotation speed of the working medium pump 15 is gradually increased from the constant speed rotation speed Rp3 with the rise of the value T and the value T is increased to a second value T2 higher than the first value T1 , The rotation speed of the working medium pump 15 is driven to the second rotation speed Rp2 which is higher than the constant rotation speed Rp3. The generator control unit 54 preferably controls the number of revolutions of the generator 20 so that the number of revolutions of the generator 20 is synchronized with that of the working medium pump 15.

As described above, in the present embodiment, in the startup control, the control means 50 determines whether the temperature T detected by the temperature sensor 32 reaches the first value T1, The rotation speed of the pump 15 is gradually increased to the constant speed Rp3 and the working medium pump 15 is rotated at the constant speed rotation speed Rp3 after the rotation speed of the working medium pump 15 reaches the constant speed rotation speed Rp3, The amount of power generation corresponding to the number of revolutions of the working medium pump 15 is obtained from the generator 20. Further, since the time for rotating at the constant rotation speed Rp3 is maintained for a predetermined time, the system of the present apparatus is stabilized.

In the second embodiment, as shown in Fig. 4, when the value T detected by the temperature sensor 32 becomes the first value T1 and the second value T2 becomes T2 The number of revolutions of the working medium pump 15 may be increased continuously until the number of revolutions of the working medium pump 15 reaches the second number of revolutions Rp2 in accordance with the rise of the value T up to 4, the point of intersection with the ordinate of the abscissa is the time when the value T detected by the temperature sensor 32 becomes the first value T1.

In addition, it should be thought that embodiment disclosed this time is an illustration and restrictive at no points. The scope of the present invention is defined by the appended claims rather than by the description of the above embodiments, and includes all modifications within the meaning and range equivalent to the claims.

For example, in the above-described embodiment, a heater of the type that is immersed in the lubricating oil or a type of heater surrounding the oil separator 13 is exemplified as the heating means 33, but the heating means 33 is limited to these It does not. As the heating means 33, a flow path 16 through which the heating medium flows may be used. In this case, the oil passage 16 is arranged around the oil separator 13 so that the heating medium flowing in the oil passage 16 can be in thermal contact with the lubricating oil in the oil separator 13. [

Although the evaporator 11 and the expander 12 in the circulating flow path 10 are shown in the above embodiment as an example in which the expander 12 is provided immediately downstream of the evaporator 11 in the circulating flow path 10, A superheater may be installed.

In the above embodiment, an example in which the IPM generator is used as the generator 20 is shown, but the generator 20 is not limited to this. As the generator 20 other than the IPM generator, for example, an induction generator may be mentioned.

In the above embodiment, the working medium pump control section 53 controls the rotation number of the working medium pump 15 only based on the value T detected by the temperature sensor 32, but the working medium pump control section 53 ) Is not limited to this. For example, after the value T detected by the temperature sensor 32 reaches the first value T1, the working medium pump control section 53 controls the rotation of the working medium pump 15 after a certain time measured by the timer The number of revolutions may be controlled to become the second rotation speed Rp2. That is, after the value T reaches the first value T1, the working medium pump control section 53 may control the number of revolutions of the working medium pump 15 based on the time other than the temperature of the lubricating oil. In this case as well, it is preferable that a period during which the working medium pump 15 shown in Fig. 3 is driven at the constant rotation speed Rp3 is set. However, it is also possible to gradually increase the number of revolutions of the working medium pump 15 with the elapse of time without setting this period.

Claims (9)

An evaporator for evaporating the working medium; an inflator for inflating the working medium; an oil separator for separating the lubricating oil discharged together with the working medium from the inflator; a condenser for condensing the working medium; A circulation flow passage in which a working medium pump for sending the medium to the evaporator is connected in series,
A generator driven by expansion of the working medium in the inflator,
A lubricating oil pump for sending lubricating oil in the oil separator to the inflator,
A temperature sensor for detecting the temperature of the lubricating oil in the oil separator,
And a control means for driving the lubricating oil pump and then performing start control for driving the working medium pump when the temperature detected by the temperature sensor reaches a predetermined value. 2. The oil separator according to claim 1, further comprising a heating means for heating the lubricating oil in the oil separator,
Wherein the control means performs control to drive the heating means simultaneously with or after the driving of the lubricating oil pump in the starting control. The control system according to claim 1 or 2, wherein in the start control, the temperature detected by the temperature sensor from the time when the temperature detected by the temperature sensor becomes the first value as the predetermined value Wherein the operating medium pump is driven at a constant rotational speed for a predetermined period of time by gradually increasing the rotational speed of the working medium pump as the temperature of the working medium pump is increased, Wherein the control unit controls the operation medium pump so that the number of revolutions of the working medium pump is gradually increased from the constant speed of rotation when the temperature detected by the temperature sensor becomes a second value higher than the first value, And controls the motor to be driven at a second rotational speed that is larger than the constant rotational speed. The control system according to claim 1 or 2, wherein, in the start control, until the temperature detected by the temperature sensor becomes a second value higher than the first value as the predetermined value, Wherein when the rotational speed of the pump is driven by the first rotational speed and the temperature detected by the temperature sensor reaches the second value, the rotational speed of the working medium pump is increased to the second rotational speed Wherein the control unit controls the drive unit to operate. 5. The compressor according to claim 4, further comprising: a bypass flow path connecting a flow path between the inflator and the evaporator, a flow path between the inflator and the oil separator, and a bypass valve provided in the bypass flow path,
Wherein the control means opens the bypass valve while the operation medium pump is being driven by the first rotation speed in the start control and while the operation medium pump is being driven by the second rotation speed, And performs control to close the bypass valve. A control method for a power generation apparatus,
The power generation apparatus includes an evaporator for evaporating the working medium, an expander for expanding the working medium, an oil separator for separating the lubricating oil discharged together with the working medium from the expander, a condenser for condensing the working medium, A circulation flow passage in which a working medium pump for sending a working medium condensed in the condenser to the evaporator is connected in series,
A generator driven by expansion of the working medium in the inflator,
A lubricating oil pump for sending lubricating oil in the oil separator to the inflator,
And a temperature sensor for detecting the temperature of the lubricating oil in the oil separator,
A lubricating oil pump driving step of driving the lubricating oil pump;
And a working medium pump driving step of driving the working medium pump when the temperature detected by the temperature sensor reaches a predetermined value. 7. The method according to claim 6, wherein in the operating medium pump driving step, as the temperature detected by the temperature sensor rises from when the temperature detected by the temperature sensor reaches the first value as the predetermined value, Wherein said control means drives said operating medium pump to rotate at a constant rotational speed for a predetermined period of time until said rotational speed reaches a constant rotational speed, Wherein the control unit controls the operation medium pump so that the number of revolutions of the working medium pump is gradually increased from the constant speed of rotation when the temperature detected by the temperature sensor becomes a second value higher than the first value, And the second rotational speed is larger than the constant rotational speed. The method according to claim 6, wherein in the operating medium pump driving step, until the temperature detected by the temperature sensor becomes a second value higher than the first value as the predetermined value, And a control unit for controlling the operation of the electric power generation apparatus when the temperature detected by the temperature sensor reaches the second value and drives the rotational speed of the working medium pump at a second rotational speed greater than the first rotational speed, Way. The power generation apparatus according to claim 8, further comprising: a bypass flow path connecting a flow path between the inflator and the evaporator, a flow path between the inflator and the oil separator, and a bypass valve provided in the bypass flow path ,
The bypass valve is opened while the working medium pump is being driven by the first rotation speed while the working medium pump is being driven by the second rotation speed, Is closed.

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