RU2479800C1 - Air conditioner - Google Patents

Abstract

FIELD: ventilation.

SUBSTANCE: in compliance with the present invention, an air conditioner capable of preventing the emission of excess heat with the element that emits the heat due to induction heating is proposed. Air conditioner (1) that includes compressor (21), external heat exchanger (23), expansion valve (24) with an electric drive and internal heat exchanger (41) includes winding (68) and control unit (11) as well. Winding (68) generates magnetic field for induction heating of cooling agent pipeline (F). Control unit (11) sets a volume rate of circulating cooling agent in a cooling cycle that includes compressor (21), internal heat exchanger (41), expansion valve (24) with an electric drive and external heat exchanger (23), and when volume rate of circulating cooling agent increases, it causes generation of magnetic field in winding (68).

EFFECT: preventing the emission of excess heat with the heating element.

7 cl, 12 dwg

Description

Technical field

The present invention relates to an air conditioner.

State of the art

In the technical field of the present invention, there is provided an air conditioner comprising a refrigerant heater that uses induction heating.

For example, Patent Document 1 described below (i.e., Japanese Unexamined Patent Application Publication No. 2007-255736) proposes an air conditioner that, in order to efficiently heat the refrigerant, controls the start of induction heating in a state in which the space velocity is provided to some extent refrigerant circulation.

SUMMARY OF THE INVENTION

Technical problem

In the technical field described in Patent Document 1 (i.e., Japanese Unexamined Patent Application Publication No. 2007-255736) discussed above, the volumetric circulation rate provided is determined to efficiently heat the refrigerant; however, the refrigerant is not subjected to direct induction heating, but rather is heated by heat transfer from a fuel element, such as a magnetic body, which itself is heated by induction heating. Therefore, even if some volumetric circulation speed can be provided to some extent, the volumetric circulation rate necessary for induction heating can sometimes not be provided.

The present invention was conceived in view of the above question, and the aim of the present invention is to provide an air conditioner capable of preventing the generation of excess heat by an element that generates heat due to induction heating.

Solution

An air conditioner in accordance with a first embodiment of the present invention, which includes at least a compression mechanism, a refrigerant cooler, an expansion mechanism and a refrigerant heater, further comprises a magnetic field generating unit, a volumetric circulation velocity setting unit, and a control unit. The magnetic field generating unit generates a magnetic field for induction heating of at least one element selected from the group consisting of a refrigerant pipe, which is designed to pump refrigerant to a compression mechanism, a refrigerant cooler, an expansion mechanism and a refrigerant heater; and an element in thermal contact with the refrigerant flowing through the refrigerant pipe. The volumetric circulation velocity setting unit sets the volumetric velocity of the circulating refrigerant of the refrigeration cycle, which includes at least a compression mechanism, a refrigerant cooler, an expansion mechanism, and a refrigerant heater. The control unit controls the magnetic field at the outlet and, with an increase in the volumetric velocity of the circulating refrigerant, set by the volumetric volumetric flow rate determining unit, performs at least one process selected from the group consisting of causing magnetic field generation by the magnetic field generation unit, increasing the magnetic field generated by the magnetic field generating unit, and increasing the upper limit of the magnetic field generated by the magnetic field generating unit.

In this air conditioner, if the space velocity at which the refrigerant is sucked in by the compression mechanism is low, there is a risk that with an increase in the magnetic field generated by the magnetic field generation unit and, therefore, an increase in the degree of induction heating, the part subjected to induction heating will generate excess heat.

On the other hand, overheating of the part subjected to induction heating can be prevented in this air conditioner, since the magnetic field is regulated, for example, due to the fact that the magnetic field is generated if the space velocity at which the refrigerant circulates has increased, while increasing intensity of the generated magnetic field, etc.

An air conditioner according to a second embodiment of the present invention is an air conditioner according to a first embodiment of the present invention, in which the magnetic field generating unit generates a magnetic field for induction heating of at least one element selected from the group consisting of a suction pipe refrigerant, which is the refrigerant piping on the low pressure side of the compression mechanism, and the element in thermal contact with the refrigerant agent, refrigerant flowing through the suction conduit.

In this air conditioner, the refrigerant, which must be absorbed by the compression mechanism, quickly heats up, and the refrigerant flowing through the refrigerant pipe, which is significantly removed from the compression mechanism, does not heat up quickly. Therefore, the refrigerant flowing from the low pressure side of the compression mechanism either has a high moisture content or is in an overheated state and, therefore, tends to increase the temperature, since its dry heat tends to change more than would be the case in which the hidden the heat of the refrigerant in a two-phase state, liquid-vapor, etc., flowing more from the pressure side.

On the other hand, in this air conditioner, since the output magnetic field is controlled after increasing the space velocity at which the refrigerant circulates, induction overheating in the state in which the space velocity at which the refrigerant circulates is low can be prevented. As a result of this, even if the refrigerant which passes from the low pressure side of the compression mechanism and which tends to increase the temperature while heating up, overheating of the part subjected to induction heating can be prevented.

An air conditioner in accordance with a third embodiment of the present invention is an air conditioner in accordance with a first embodiment or a second embodiment of the present invention, in which the volumetric circulation velocity setting unit is determined based on at least a predetermined working volume of the compression mechanism cylinder, defining the frequency of the compression mechanism and the density of the refrigerant absorbed by the compression mechanism.

In this air conditioner, the control of the magnetic field at the outlet can be carried out in accordance with the state of the refrigerant passing on the low pressure side of the compression mechanism.

An air conditioner according to a fourth embodiment of the present invention is an air conditioner according to a third embodiment of the present invention, further comprising a low pressure setting unit and a suction refrigerant temperature setting unit. The low pressure setting unit sets the pressure of the refrigerant flowing in the low pressure section of the refrigeration cycle. The unit for determining the temperature of the suction refrigerant sets the temperature of the refrigerant sucked in by the compression mechanism. The unit for establishing the volumetric circulation velocity obtains the density of the refrigerant absorbed by the compression mechanism based on the pressure set by the low-pressure unit and the temperature set by the unit for setting the temperature of the suction refrigerant.

In this air conditioner, the space velocity with which the refrigerant circulates can be set more precisely.

An air conditioner according to a fifth embodiment of the present invention is an air conditioner according to a fourth embodiment of the present invention, wherein the suction refrigerant temperature setting unit is on the low pressure side of the compression mechanism in the refrigeration cycle and registers a quantity parameter of the refrigerant passing on the discharge side of the portion, subjected to induction heating by the magnetic field generation unit.

In this air conditioner, a value that is not affected by induction heating can be set by setting a quantitative parameter for the refrigerant that flows on the pressure side of the portion that generates heat by induction heating.

An air conditioner according to a sixth embodiment of the present invention is an air conditioner according to a fourth embodiment of the present invention, in which the control unit controls the output magnetic field in each case selected from the group consisting of the case in which the suction refrigerant of the compression mechanism is in the wet state, and the case in which the suction refrigerant of the compression mechanism is in an overheated state, and the degree of overheating is Chez predetermined degree of superheat.

In this air conditioner, if the degree of overheating of the refrigerant absorbed by the compression mechanism is high, then there is a risk that the temperature rise of the area that generates heat due to induction heating will be significant.

On the other hand, in this air conditioner, induction heating is carried out if and only if an overheated state is achieved in which the degree of overheating is less than the specified degree of overheating, or when a wet state is reached. Therefore, even if the reference frequency of the compression mechanism is high, and the speed with which the refrigerant flows is substantial, the magnetic field at the outlet is not controlled until either an overheated state is achieved, in which the degree of superheat is less than the specified degree of superheat, or wet a condition that allows more prevent excessive overheating.

An air conditioner according to a seventh embodiment of the present invention is an air conditioner according to any one of the first to sixth embodiments of the present invention, in which the control unit controls the output magnetic field if the volumetric speed of the circulating refrigerant set by the volumetric volumetric speed setting unit is greater than set value.

In this air conditioner, if the output magnetic field is controlled, and in the area subjected to induction heating, heat is generated in a state in which the volume velocity at which the refrigerant circulates exceeds a predetermined value, the large amount of refrigerant that passes through the surrounding area prevents evolution heat. In this case, the generation of excess heat of the induction-heated section can be reliably prevented.

Beneficial effects of the invention

In the air conditioner according to the first embodiment of the present invention, overheating of the induction-heated portion of the area can be prevented.

In the air conditioner according to the second embodiment of the present invention, the overheating of the induction-heated portion can be prevented even if the refrigerant which flows from the low pressure side of the compression mechanism and thereby tends to increase the temperature is heated.

In the air conditioner according to the third embodiment of the present invention, the output magnetic field can be controlled in accordance with the state of the refrigerant which extends from the low pressure side of the compression mechanism.

In an air conditioner according to a fourth embodiment of the present invention, the volumetric flow rate of the refrigerant can be set with greater accuracy.

In an air conditioner according to a fifth embodiment of the present invention, a value not affected by induction heating can be set.

In an air conditioner according to a sixth embodiment of the present invention, excessive overheating can be prevented to a greater extent.

In an air conditioner in accordance with a seventh embodiment of the present invention, the generation of excess heat of the induction-heated portion of the area can be reliably prevented.

Brief Description of the Drawings

1 is a schematic diagram of a refrigerant circuit of an air conditioner in accordance with one embodiment of the present invention.

Figure 2 shows an external view at an angle of the induction heating unit.

FIG. 3 is an oblique exterior view showing a state in which the protective cover is removed from the induction heating unit.

Figure 4 shows an external view at an angle of the induction thermistor.

Figure 5 shows an external view at an angle of the protective device.

6 is a schematic sectional view showing a state in which an induction thermistor and a protective device are installed.

Figure 7 shows a section of an induction heating unit.

On Fig shows a block diagram of the control of induction heating with moisture protection.

Figure 9 shows a block diagram of the control to prevent abnormal overheating.

Figure 10 shows an example of a refrigerant piping diagram in accordance with another embodiment (H).

11 shows an example of a refrigerant piping diagram in accordance with another embodiment (I).

12 is a view showing an example of a ferrite rim in accordance with another embodiment (J).

Description of Embodiments

Below, with reference to the drawings, a typical example of an air conditioner 1, which comprises an induction heating unit 6, in accordance with one embodiment of the present invention, is explained.

First Embodiment

1-1 Air conditioning 1

Figure 1 shows a schematic hydraulic diagram of a refrigerant, which shows a circuit for the circulation of refrigerant 10 of the air conditioner 1.

The air conditioner 1 is a device in which the outdoor unit 2 serving as the device of the side of the heat source and the indoor unit 4 serving as the device of the side of use are connected via a refrigerant pipe and the space in which the device of the side of use is located is conditioned ; in addition, the air conditioner 1 includes a compressor 21, a four-way switching valve 22, an external heat exchanger 23, 24 electric expansion, an accumulator 25, external fans 26, an internal heat exchanger 41, an internal fan 42, a hot gas bypass valve 27, a capillary tube 28, block 6 induction heating, etc.

A compressor 21, a four-way switching valve 22, an external heat exchanger 23, an expansion valve 24 with an electric actuator, a battery 25, outdoor fans 26, a bypass hot gas valve 27, a capillary tube 28 and an induction heating unit 6 are placed in the outdoor unit 2. The internal heat exchanger 41 and the internal a fan 42 is placed in the indoor unit 4.

The refrigerant circuit 10 includes a pressure pipe A, an internal gas pipe B, an internal liquid pipe C, an external liquid pipe D, an external gas pipe E, a drain pipe F of the battery, a suction pipe G, and a hot gas bypass circuit H. A large amount of refrigerant in the gas state passes through the inner gas pipe B and the outer gas pipe E, but the refrigerant passing through these pipes is not limited to the gas state. A large amount of refrigerant in the liquid state passes through the inner fluid pipe C and the outer fluid pipe D, but the refrigerant passing through the pipes is not limited to the liquid state.

A pressure pipe A connects the compressor 21 and a four-way switching valve 22. A pressure sensor 29d is provided in the pressure pipe A, which detects the temperature of the refrigerant passing through the pressure pipe A. In addition, the electric current supply unit 21e supplies electric current to the compressor 21. Electric power supplied by the electric current supply unit 21e is registered by the compressor electric power registration unit 29f. In addition, the rotational speed detection unit 29r detects the rotational speed of the piston of the compressor 21. The internal gas pipe B connects the four-way switching valve 22 and the internal heat exchanger 41. A first pressure sensor 29a that senses the pressure of the refrigerant passing through the internal gas pipe B is provided along the internal gas pipe B. The inner fluid pipe C connects the internal heat exchanger 41 and the expansion valve 24 with an electric actuator. The outer fluid pipe D connects the expansion valve 24 to the electric actuator and the outdoor heat exchanger 23. The outer gas pipe E connects the outdoor heat exchanger 23 and the four-way switching valve 22. A second pressure sensor 29g that senses the pressure of the refrigerant passing through the outer gas pipe E is provided along the outer gas tube E.

The drainage tube F of the battery connects the four-way switching valve 22 and the battery 25 and in the state in which the battery 25 is installed in the outdoor unit 2, passes in vertical directions. The induction heating unit 6 is fixed to a part of the drainage tube F of the battery. At least the heat-radiating portion of the drainage tube F of the battery, which is surrounded by a winding 68 (described below), comprises a magnetically deflected tube F2 such that it surrounds the copper tube F1 through which the refrigerant flows. The magnetic deflection tube F2 is made of stainless steel (SUS) 430. SUS 430 is a ferroelectric material; when it is placed in a magnetic field, eddy currents are induced that generate heat due to the action of the Joule heat caused by the material’s own electrical resistance. The pipeline section constituting the refrigerant circulation circuit 10 and located outside the magnetic deflection tube F2 contains copper tubes. Due to the implementation of induction heating in this way, the magnetic deflection tube F can generate heat due to electromagnetic induction, and therefore, the refrigerant that is sucked into the compressor 21 through the battery 25 can be heated. Therefore, the heat capacity of the air conditioner 21 can be improved. In this case, for example, even if the compressor 21 is not sufficiently heated at the start of the heating process, the induction heating unit 6 can carry out rapid heating, thereby making up for the insufficient heat capacity at startup. In addition, if the four-way switching valve 22 switches to the cooling process state and a defrosting process is performed that eliminates the frost released on the external heat exchanger 23 and the like, then the compressor 21 can compress the rapidly heated refrigerant thanks to the induction heating unit 6, which quickly heats up drain pipe F of the battery. Therefore, the temperature of the hot gas injected from the compressor 21 can be rapidly increased. At the same time, the time required to thaw frost during defrosting can be reduced. Moreover, even if it is necessary to carry out the defrosting process, when appropriate, it is possible to return to the defrosting process in a minimum time and thereby increase user convenience.

In addition, in the drainage tube of the battery F, there is a suction temperature sensor 19 that detects the temperature of the refrigerant that flows between the induction heating unit 6 and the four-way switching valve 22. In the state in which the refrigeration cycle performs the heating process, the suction temperature sensor 19 detects the temperature of the refrigerant, proceeding on the exhaust side of the induction heating unit 6 before heating the refrigerant by induction heating using the induction heating unit 6 .

A suction tube G connects the accumulator 25 and the low pressure side of the compressor 21.

The hot gas bypass circuit H connects the branch point A1, which is provided along the discharge pipe A, and the branch point D1, which is provided along the outer fluid pipe D. The hot gas bypass valve 27, capable of switching between a state in which refrigerant flows through the bypass circuit H hot gas, and the state in which it is not provided, is located along the bypass circuit of the hot gas N. In addition, the capillary tube 28, which lowers the pressure of the refrigerant, passing through the hot gas bypass circuit H is provided along the hot gas bypass circuit H between the hot gas bypass valve 27 and the branch point D1. Since the refrigerant pressure may approach the refrigerant pressure after the pressure has been reduced by the electric expansion valve 24 during the heating process, capillary tube 28 may prevent the refrigerant pressure from rising in the outer fluid pipe D by supplying hot gas that has passed through the hot gas bypass circuit H into the outer fluid tube D.

The four-way switching valve 22 is configured to switch between the cycle of the cooling process and the cycle of the heating process. 1, solid lines show the state of the connection in which the heating process is performed, and dashed lines show the state of the compound in which the cooling process is performed. During the heating process, the outdoor heat exchanger 23 functions as a refrigerant heater. During the cooling process, the external heat exchanger 23 performs the function of a refrigerant cooler, and the internal heat exchanger 41 performs the function of a refrigerant heater.

One end of the external heat exchanger 23 is connected to the end part of the external gas tube E from the side of the external heat exchanger 23, and the other end of the external heat exchanger 23 is connected to the end part of the external liquid tube D from the side of the external heat exchanger 23. In this, the outdoor heat exchanger 23 has an outdoor temperature sensor 29c a heat exchanger that senses the temperature of the refrigerant flowing through the air conditioner 1. In addition, an outside temperature sensor 29b that senses an outside air temperature ear, there is an external heat exchanger 23 from the lower side in the air flow.

An internal temperature sensor 43, which senses the internal temperature, is available in the indoor unit 4. In this case, an internal heat exchanger temperature sensor 44, which senses the temperature of the refrigerant on the inside of the fluid pipe C, along which the electric expansion valve 24 is connected, is present in the internal heat exchanger 41.

The control unit 11 is formed by connecting the outdoor control unit 12, which controls the equipment located in the outdoor unit 2, and the indoor control unit 13, which controls the equipment located in the indoor unit 4, using the communication wire 11a. The control unit 11 performs various control functions with respect to the air conditioner 1.

Moreover, a timer 95 is provided on the outdoor control unit 12, which counts down to measure elapsed time when performing various control functions.

In addition, a controller 90 is connected to the control unit 11, which accepts user-entered settings.

1-2 Unit 6 induction heating

Figure 2 schematically depicts an external view at an angle of the induction heating unit 6 mounted on the drainage tube F of the battery. FIG. 3 is an oblique exterior view showing a state in which the protective cover 75 is removed from the induction heating unit 6. FIG. 4 is an externally oblique view of the induction thermistor 14. FIG. 5 is an oblique external view of the protector 15. FIG. 6 is a schematic sectional view showing a state in which an induction thermistor 14 and a protective device 15 are mounted on the drainage tube F of the battery. 7 shows a section of a block 6 of induction heating mounted on the drainage tube F of the battery.

The induction heating unit 6 is positioned so that it closes the magnetic deflection tube F2, which is the heat-generating part of the drainage tube F of the battery, from the outside in radial directions and causes heat generation in the magnetic deflection tube F2 due to induction heating. The heat-generating part of the drainage tube F of the battery has a double tube design that includes a copper tube F1 on the inside and a tube F2 with a magnetic deflection on the outside.

The induction heating unit 6 comprises a first hex nut 61, a second hex nut 66, a first coil cover 63, a second coil cover 64, a coil main body 65, a first ferrite frame 71, a second ferrite frame 72, a third ferrite frame 73, a fourth ferrite frame 74, first ferrite nodes 98, second ferrite nodes 99, winding 68, protective cover 75, induction thermistor 14, protective device 15, and the like.

The first hex nut 61 and the second hex nut 66 are made of resin, while the induction heating unit 6 and the drainage tube F of the battery are rigidly fixed with a spring ring (not shown). The first coil cover 63 and the second coil cover 64 are made of resin and close the drainage tube F of the battery externally in radial directions in the upper end position and the lower end position, respectively. Both the first coil cover 63 and the second coil cover 64 have four threaded holes for screwing the first to fourth frames 71-74 (described below) of the ferrite to the first coil cover 63 and the second coil cover 64 using bolts 69. In addition in addition, in the second coil cover 64 there is an induction thermistor mounting hole 64f for inserting the induction thermistor 14 into the second coil cover 64 for installing the induction thermistor 14 on the outer surface of the magnetic deflection tube F2. At the same time, in the second coil cover 64 there is a mounting hole 64e of the protective device for inserting the protective device 15 into the second coil cover 64 for mounting the protective device 15 on the outer surface of the magnetic deflection tube F2. As shown in FIG. 4, the induction thermistor 14 comprises an induction thermistor registration unit 14a, an outer protrusion 14b, a side protrusion 14c, and induction thermistor wire connections 14d that convert the registration result of the induction thermistor registration unit 14a into a signal and transmit it to the control unit 11. The induction thermistor registration unit 14a has a shape corresponding to the curved shape of the outer surface of the drainage tube F of the battery, and has a significant contact surface area. As shown in FIG. 5, the protection device 15 comprises a registration device 15a of the protection device, an asymmetric shape element 15b and wire connections 15d of the protection device that convert the registration result of the registration device 15a of the protection device into a signal and transmit it to the control unit 11. If the control unit 11 receives a notification from the protection device 15 that the detected temperature exceeds a predetermined limit, the control unit 11 controls so that the power supply to the winding 68 is cut off, thereby avoiding thermal damage to the equipment. The main body 65 of the coil is made of resin, with the winding 68 being wound around the main body 65 of the coil. The coil 68 is wound in a spiral around the outside of the main body 65 of the coil, with the directions in which the drainage tube F of the battery passes are axial directions. The coil 68 is connected to a control circuit board (not shown) and receives a supplied high frequency electric current. The control output of the control circuit board is carried out using the control unit 11. As shown in FIG. 6, the induction thermistor 14 and the protective device 15 are installed in a state in which the main coil body 65 and the second coil cover 64 are connected. In this case, in the state in which the induction thermistor 14 is installed, an acceptable pressure contact between the induction thermistor 14 and the outer surface of the magnetic deflection tube F2 is supported by a leaf spring 16, which presses the induction thermistor 14 inward in the radial directions of the magnetic deflection tube F2. However, in the state in which the protective device 15 is installed, an equally acceptable pressure contact between the protective device 15 and the outer surface of the magnetic deflection tube F2 is maintained by means of a leaf spring 17, which presses the protective device 15 inward in the radial directions of the magnetic tube F2 deviation. Moreover, since tight contact is properly maintained between the induction thermistor 14 and the outer surface of the battery tube F, as well as between the protective device 15 and the outer surface of the battery tube F, the sensitivity is increased, and sudden changes in temperature due to induction heating can be quickly detected. The first ferrite rim 71 is inserted into the first coil cover 63 and the second coil cover 64 in the directions along which the battery tube F extends and secured with bolts 69. Each of the frames from the first 71 to the fourth 74 ferrite accommodates the first ferrite nodes 98 and the second nodes 99 ferrites, which are made from ferrite - a starting material having high magnetic permeability. As shown in the section of the battery tube F and the induction heating unit 6 in FIG. 7, due to the capture of the magnetic field generated by the winding 68, and thereby the formation of the magnetic flux path, the first ferrite nodes 98 and the second ferrite nodes 99 tend to have no external leakage magnetic field. The protective cover 75 is located at the farthest from the middle of the circumferential part of the induction heating unit 6 and collects magnetic flux, which cannot be completely collected by the first ferrite nodes 98 and the second ferrite nodes 99 separately. In this case, practically no leakage of magnetic flux to the outside of the protective cover 75 occurs; in addition, the location at which the magnetic flux is generated can be determined independently.

1-3 Induction heating control

A control is performed in which the induction heating unit 6 discussed above causes heat to be generated by the tube F2 with a magnetic deflection of the drainage tube F of the battery when starting, that is, the heating process is started when the heating process is triggered in the refrigeration cycle, when the heating efficiency increases and when the defrosting process is performed .

Below, as an example of various types of control carried out by the induction heating unit 6 while increasing the heating efficiency, control is explained in order to prevent an abnormal increase in the temperature of the tube F2 with a magnetic deflection of the drainage tube F of the battery.

Abnormal Overheat Prevention Management

The abnormal overheat prevention control is a control that is performed after the control is completed when the compressor 21 and the like are started, in order to verify the state of normal control in which the state of distribution of the refrigerant in the refrigerant circulation circuit 10 of the air conditioner 1 is stabilized in that the space velocity with which the refrigerant circulates through the drainage tube F of the battery, is sufficiently ensured when the induction heating unit 6 starts induction heating, for example er, to increase the heat capacity of the work.

In this case, the control unit 11 calculates the volumetric rate with which the refrigerant circulates in the refrigeration cycle (i.e., the volumetric rate with which the refrigerant passes through the tube F2 with the magnetic deflection of the drainage tube F of the battery) by multiplying the working volume of the cylinder of the compressor 21, which is stored in memory (not shown) in the form of a predetermined value, the rotational speed of the compressor drive 21, which is set using the rotational speed setting unit 29r, and the density of the refrigerant sucked into the compressor 21. The density is sucked of the refrigerant is calculated by the control unit 11 based on the refrigerant pressure detected by the second pressure sensor 29g and the refrigerant temperature detected by the suction temperature sensor 19.

In the state of normal control, which is the state achieved after the end of various types of control performed when the air conditioner 1 is started, the control unit 11 in the state in which the reference frequency of the compressor 21 is maintained at the maximum permissible frequency, performs control responsive to changes, such as a change in the temperature of the outside air and a change in the user-set initial temperature, by changing the space velocity of the circulating refrigerant due to the regulation the degree of opening of the valve 24 expansion with electric drive. In this case, the control unit 11 controls the degree of opening of the electric expansion valve 24 so that the degree of subcooling of the refrigerant that passes between the internal heat exchanger 41 and the electric expansion valve 24 is maintained at a temperature of 5 ° C during the heating process. This degree of subcooling is achieved using the control unit 11, which calculates the difference between the saturation temperature corresponding to the pressure detected by the second pressure sensor 29g and the temperature detected by the temperature sensor of the internal heat exchanger 44.

The following explanation refers to a control block diagram for preventing abnormal moisture overheating shown in FIG.

In step S11, the control unit 11 determines whether a normal control state has been reached. Moreover, if it is established that the normal control state is reached, then this method proceeds to step S12. In addition, in the normal control state, the output signal of the induction heating unit 6 is zero.

In step S12, the control unit 11 determines whether the space velocity with which the refrigerant circulates in the refrigeration cycle is greater than or equal to the set space velocity to prevent abnormal overheating. If it is less than the space velocity to prevent abnormal overheating, this method repeats step S12. If it is greater than or equal to the space velocity to prevent abnormal overheating, this method proceeds to step S13.

In step S13, the control unit 11 causes, in the induction heating unit 6, the induction heating of the drainage tube F of the battery to start.

In step S14, the control unit 11 waits for a predetermined time to elapse while maintaining an existing control state.

In step S15, the control unit 11 again determines whether the space velocity with which the refrigerant circulates in the refrigeration cycle is greater than or equal to the set space velocity to prevent abnormal overheating. If it is greater than or equal to the space velocity to prevent abnormal overheating, then this method returns to step S14. If it is less than the space velocity to prevent abnormal overheating, this method proceeds to step S16.

In step S16, the control unit 11 causes, in the induction heating unit 6, to stop the induction heating of the battery drain tube F.

Thereby, an abnormal increase in the temperature of the drainage tube F of the battery can be prevented by ensuring the flow of refrigerant in the drainage tube F of the battery when the induction heating unit 6 performs induction heating.

Characteristics of Air Conditioner 1 in First Embodiment

In the air conditioner 1, the prevention of abnormal overheating is controlled before induction heating of the drainage tube F of the battery by the induction heating unit 6, in order to first check whether the achieved state is the state in which the space velocity with which the refrigerant circulates in the refrigeration cycle is greater than or equal to the space velocity prevent abnormal overheating. Therefore, the induction heating unit 6 performs induction heating only in a state in which the refrigerant flows in the refrigeration cycle with a space velocity that is greater than or equal to the space velocity to prevent abnormal overheating, and not in a state in which the space velocity is less than the space velocity to prevent abnormal overheating.

As a result, heat supplied to the drainage tube F of the battery by induction heating by the induction heating unit 6 is taken away by the circulating refrigerant, and therefore, an abnormal increase in the temperature of the drainage tube F of the battery can be prevented because a sufficient volumetric rate of circulation of the refrigerant is ensured.

Second Embodiment

The configuration of the air conditioner in accordance with the second embodiment is similar to the configuration of the above air conditioner 1 in accordance with the first embodiment, therefore, its description is omitted.

In the air conditioner according to the second embodiment, the moisture protection control to prevent abnormal overheating is performed instead of the abnormal overheat prevention control according to the first embodiment.

Management of moisture protection to prevent abnormal overheating is a control that is performed after the end of control when starting the compressor 21, etc. in order to check when the induction heating unit 6 induces heating to increase the heat capacity, to ensure a sufficient volumetric speed of the refrigerant circulating through the drainage tube F of the battery when the induction heating unit 6 starts induction heating so that no liquid compression occurs in the compressor 21. Moreover, when the induction heating unit 6 performs induction heating to increase the heat capacity, the power supplied to the winding 68 is set at 50% of the maximum output power.

In the state in which the induction heating unit 6 performs induction heating to increase the heat capacity, which is the state achieved after the end of various types of control performed when the air conditioner 1 is started, the control unit 11 is in a state in which the reference frequency of the compressor 21 is maintained at the maximum permissible frequency reacts to state changes, such as a change in the temperature of the outside air, a change in a user-set initial temperature, etc., by changing WHSV of Ia circulating refrigerant by regulating the valve opening 24 Expansion Power. At the same time, the control unit 11 controls the degree of opening of the electrically operated expansion valve 24 so that the degree of subcooling of the refrigerant that passes between the internal heat exchanger 41 and the expansion valve 24 with the electric actuator is maintained at a temperature of 5 ° C during the heating process. This degree of subcooling is achieved using the control unit 11, which calculates the difference between the saturation temperature corresponding to the pressure detected by the second pressure sensor 29g and the temperature detected by the temperature sensor of the internal heat exchanger 44.

The control unit 11 calculates the moisture content or the degree of overheating of the refrigerant absorbed by the compressor 21 based on the difference between the saturation temperature corresponding to the pressure detected by the second pressure sensor 29g and the temperature detected by the induction thermistor 14.

The control unit 11 calculates the moisture content or the degree of overheating of the refrigerant pumped by the compressor 21 based on the difference between the saturation temperature corresponding to the pressure detected by the first pressure sensor 29a and the temperature detected by the discharge temperature sensor 29d.

The following explanation refers to a moisture protection control block diagram for preventing abnormal overheating shown in FIG. 9.

In step S21, the control unit 11 determines whether the induction heating unit 6 induces heating. Moreover, if it is determined that induction heating is currently being performed, this method proceeds to step S22. If induction heating is not currently performed, then this method repeats step S21.

In step S22, the control unit 11 determines whether the induction heating start condition is satisfied in which the degree of superheat of the suction refrigerant is less than 4 ° C and the degree of superheat of the charge refrigerant is less than 10 ° C. If the start condition for induction heating is not satisfied, then this method repeats step S22. If the start condition for induction heating is satisfied, then this method proceeds to step S23.

At step S23, the control unit 11 determines whether the space velocity with which the refrigerant circulates in the refrigeration cycle is greater than or equal to the set space velocity to prevent abnormal overheating at maximum output power. If it is less than the space velocity to prevent abnormal overheating at maximum output power, this method repeats step S23. If it is greater than or equal to the space velocity to prevent abnormal overheating at maximum output power, this method proceeds to step S24.

In step S24, the control unit 11 increases the degree to which the induction heating unit 6 induces heating of the battery drain tube F. That is, the power of the electric power supplied to the winding 68 of the induction heating unit 6 is increased. In this case, the power of the electric power supplied to the winding 68 increases from the state in which it leaves 50% of the maximum output power to the state in which it leaves the maximum output power.

In step S25, the control unit 11 waits for a predetermined time to elapse while maintaining an existing control state.

In step S26, the control unit 11 again determines whether the space velocity with which the refrigerant circulates in the refrigeration cycle is greater than or equal to the set space velocity to prevent abnormal overheating at maximum output power. If it is greater than or equal to the space velocity to prevent abnormal overheating at maximum output power, this method proceeds to step S27. If it is less than the space velocity to prevent abnormal overheating at maximum output power, this method proceeds to step S28.

In step S27, the control unit 11 determines whether the condition for stopping the induction heating is satisfied in which the degree of superheat of the suction refrigerant is greater than or equal to 5 ° C or the degree of superheat of the injected refrigerant is greater than or equal to 12 ° C. If the condition for stopping the induction heating is not satisfied, then this method returns to step S25. If the condition for stopping the induction heating is satisfied, then this method proceeds to step S28.

In step S28, the control unit 11 reduces the output power of the induction heating unit 6 by inductionally heating the drainage tube F of the battery to 50% of the maximum output power, which is a state in which the heating efficiency is increased.

Thus, even if the output power of the induction heating of the induction heating unit 6 increases, an abnormal increase in the temperature of the drainage tube F of the battery can be prevented by preventing compression of the liquid in the compressor 21 by ensuring fluidity of the refrigerant in the drainage tube F of the battery.

Characteristics of Air Conditioner 1 According to Second Embodiment

When controlling moisture protection to prevent abnormal overheating in the second embodiment, not only the characteristics of the above-mentioned first embodiment can be achieved, but also compression of the liquid in the compressor 21 and an abnormal increase in the temperature of the drainage tube F of the battery can be prevented.

In addition, if in the second embodiment, the output power of the induction heating unit 6 is further increased, while the induction heating unit 6 performs induction heating at an output power of 50% in order to increase the heating efficiency, it is difficult to establish whether the space velocity with which the refrigerant circulates in the area subjected to induction heating by the induction heating unit 6, since the temperature recorded by the induction thermistor 14 has already risen. In contrast, in the air conditioner 1 of the second embodiment, the suction temperature sensor 19 is installed in some position on the discharge side of the portion subjected to induction heating by the induction heating unit 6. Therefore, with respect to the space velocity with which the refrigerant circulates in the refrigeration cycle, it is possible to establish the space velocity with which the refrigerant flows on the pressure side of the portion subjected to induction heating by the induction heating unit 6, by obtaining the density of the refrigerant rather than the space velocity with which the refrigerant flows between the predetermined induction heating section and the compressor 21 in the state after heating the refrigerant. In addition, if the indicated volumetric circulation speed is the volumetric rate of preventing abnormal overheating at maximum output power, then the control unit 11 allows you to set the output power of the induction heating unit 6 to a maximum. Thus, even if the induction heating unit 6 performs induction heating at the maximum output power, an abnormal increase in the temperature of the induction-heating portion can be prevented.

Other options for implementation

In the above description, an embodiment of the present invention is explained based on the drawings, but the specific construction is not limited to these embodiments, and it should be understood that various embodiments are possible within the spirit and scope of the invention.

(BUT)

In the above embodiment, a typical example is explained in which SUS 430 is used as the material of the magnetic deflection tube F2.

However, the present invention is not limited to this. For example, it can be a conductor, such as iron, copper, aluminum, chromium, nickel, etc., or an alloy containing at least two metals selected from this group.

In addition, the magnetic material can be, for example, one of two types, namely ferritic or martensitic, or a mixture thereof, but preferably a material that is ferromagnetic and has a relatively high electrical resistance and Curie temperature above the temperature of the operating temperature range.

Moreover, the drainage tube F of the battery in this case requires more power supply; however, instead of a magnetic body and a material containing a magnetic body, it may contain material capable of undergoing induction heating.

Moreover, for example, the magnetic material can form the entire drainage tube F of the battery, only the inside of the drainage tube F of the battery or simply be part of the material forming the pipeline of the drainage tube F of the battery.

(AT)

In the aforementioned second embodiment, a typical example is explained in which the moisture content or the degree of overheating of the refrigerant drawn in by the compressor 21 is set based on the temperature recorded by the induction thermistor 14.

However, the present invention is not limited to this.

For example, in the induction thermistor 14 it is difficult to register the temperature of the refrigerant flowing through the area undergoing induction heating, while the induction heating unit 6 performs induction heating, and therefore, a higher temperature is sometimes spontaneously recorded due to the heat generated by the magnetic deflection tube F2.

In this case, in addition, between the low pressure side of the compressor 21 and the area subjected to induction heating, instead of the induction thermistor 14, a sensor can be provided that senses the temperature of the drainage tube F of the battery in a place separate from the area subjected to induction heating, so that any error in heat transfer due to induction heating may not be taken into account. Thus, even at the time when induction heating is carried out, the moisture content or the degree of overheating of the refrigerant absorbed by the compressor 21 can be established with greater accuracy.

(FROM)

The induction heating start condition and the induction heating stop condition of the first embodiment and the induction heating start condition, and the induction heating stop condition of the second embodiment are explained in accordance with typical examples in which the same conditions were established.

However, the present invention is not limited to this. For example, moisture protection control to prevent abnormal overheating in the second embodiment is a control in which the output of the induction heating unit 6 when performing induction heating is already 50% and then further increased to the maximum output power. Therefore, the induction heating start condition to increase the output power to the maximum value (i.e., the induction heating start condition in the second embodiment) can be set such that the refrigerant sucked in by the compressor 21 is in a wetter state than under the start condition induction heating according to the first embodiment.

(D)

In the second embodiment, a typical example is explained in which if the space velocity of the circulating refrigerant is greater than or equal to the space velocity of preventing abnormal overheating at the maximum output power, the output power of the induction heating unit 6 is increased from 50% to the maximum value.

However, the present invention is not limited to this. For example, the output of the induction heating unit 6 can be adjusted in accordance with the obtained space velocity of the circulating refrigerant.

(E)

In the first and second embodiments, typical examples are explained in which it is established whether the volumetric rate of preventing abnormal overheating is reached or whether the volumetric rate of preventing abnormal overheating is reached at maximum output power.

However, the present invention is not limited to this. For example, if the output of the induction heating unit 6 cannot be increased due to the space velocity to prevent abnormal overheating, the space velocity to prevent abnormal overheating at the maximum output power or something like that cannot be achieved, control can be performed that increases the speed of the compressor 21 , and a state can be achieved in which the heat capacity of the induction heating by the induction heating unit 6 can actively increase without concomitant abnormal increasing the temperature of the area undergoing induction heating.

F

In the aforementioned first embodiment, a typical example is explained in which the state of the refrigerant in the refrigeration cycle is stabilized by continuously controlling the degree of subcooling.

However, the present invention is not limited to this.

For example, control can be performed in which the degree of change in the state of distribution of the refrigerant in the refrigeration cycle is maintained at a predetermined distribution state or within a predetermined distribution interval for a predetermined time. With regard to detecting a distribution state of a refrigerant, for example in front of a refrigeration cycle condenser, a sight glass or the like may be provided, wherein a distribution state of a refrigerant can be set using a sight glass to establish a level of liquid refrigerant; moreover, control can be carried out to stabilize the distribution state so that it is at the level of a predetermined distribution state or within a predetermined distribution interval.

(G)

In the above embodiments, a typical example is explained in which the induction heating unit 6 is mounted on the drain tube F of the battery of the refrigerant circuit 10.

However, the present invention is not limited to this.

For example, an induction heating unit may be installed on a refrigerant pipe other than the drainage tube F of the battery. In this case, a magnetic body, for example a magnetic deflection tube F2, is provided in a portion of the refrigerant pipe in which the induction heating unit 6 is provided.

(H)

In the above embodiments, a typical example is explained in which the drainage tube F of the battery is made in the form of a double tube, namely in the form of a copper tube F1 and a tube F2 with a magnetic deflection.

However, the present invention is not limited to this.

As shown in FIG. 10, for example, an element of the magnetic body F2a and two clips F1a, F1b may be located inside the drainage tube F of the battery, a heated refrigerant pipe, and the like. Moreover, the element of the magnetic body F2a contains magnetic material and generates heat due to induction heating according to the aforementioned embodiment. In two places on the inner side of the copper tube F1, the retainers F1a, F1b continuously provide the passage of refrigerant, but do not allow the element of the magnetic body F2a to pass. Moreover, the element of the magnetic body F2a does not move even when the refrigerant is moving. Therefore, a predetermined heating position of the drainage tube F of the battery and the like can be heated. Moreover, heat transfer efficiency can be improved since the heat generating element of the magnetic body F2a and the refrigerant are in direct contact with each other.

(I)

Instead of using the clips F1a, F1b, the position of the magnetic body member F2a, explained in the aforementioned other embodiment (H), can be set relative to the pipeline.

As shown in FIG. 11, for example, curved portions FW can be provided in two places on the copper tube F1, and an element of the magnetic body F2a can be located on the inside of the copper tube F1 between the two curved sections FW. Thus, in addition, the movement of the element of the magnetic body F2a can be restrained while passing the refrigerant.

(J)

In the above embodiments, an example is explained in which the winding 68 is spirally wound around the drainage tube of the battery F.

However, the present invention is not limited to this.

As shown in FIG. 12, for example, windings 168 that are spirally wound around the coil main bodies 165 are located around the perimeter without being wound around the battery drain tube F. Moreover, each of the main body 165 of the coil is positioned so that its axial directions are essentially perpendicular to the axial directions of the drainage tube F of the battery. However, two pairs, in which each pair contains one of the main body 165 of the coil and one of the windings 168, are arranged so that a drainage tube F of the battery is placed between them. In such a case, as shown in FIG. 12, the first coil cover 163 and the second coil cover 164 into which the battery drain tube F is inserted are preferably in a state in which they are mated with the main coil bodies 165. However, as shown in FIG. 12, the first coil cover 163 and the second coil cover 164 are preferably placed between the first ferrite frame 171 and the second ferrite frame 172 and are thereby fixed.

12 shows a typical example in which two ferrite frames 171, 172 are provided in such a way that a drainage tube F of the battery is placed between them; however, as in the aforementioned embodiments, the ferrite frames may be arranged in four directions around the drainage tube F of the battery. However, as in the aforementioned embodiments, ferrite components may be located there.

Other

In the above description, embodiments of the present invention are explained with some examples, but the present invention is not limited to these embodiments. For example, the present invention also includes other combined embodiments obtained by correspondingly combining portions of the aforementioned embodiments within the scope of embodiments that may be implemented by one skilled in the art based on the scope of the invention described above.

Industrial applicability

The present invention is able to prevent the generation of excess heat by an element that generates heat due to induction heating, and is therefore particularly useful in an air conditioner capable of heating a refrigerant by electromagnetic induction.

List of Reference Items

1 Air conditioning

11 control unit

19 Intake temperature sensor (intake refrigerant temperature setting unit)

21 Compressor (compression mechanism)

23 External heat exchanger (refrigerant heater)

24 Electric expansion valve (expansion mechanism)

29a first pressure sensor

29g Second pressure sensor (low pressure setting unit)

29r Node establishing the frequency of rotation (node establishing volumetric circulation velocity)

41 Internal heat exchanger

44 Internal heat exchanger temperature sensor

68 Winding (magnetic field generation unit)

F Battery drain pipe

List of bibliographic references

Patent Literature

Patent Document 1

Japanese Unexamined Patent Publication No. 2007-255736.

Claims (7)

1. Air conditioning (1) includes at least a compression mechanism (21), a refrigerant cooler (41), an expansion mechanism (24), and a refrigerant heater (23), comprising:
a magnetic field generating unit (68) that generates a magnetic field for induction heating of at least one element selected from the group consisting of a refrigerant pipe (F), which is designed to pump refrigerant to the compression mechanism (21), a cooler (41 ) refrigerant, expansion mechanism (24) and refrigerant heater (23); and an element in thermal contact with the refrigerant flowing through the refrigerant pipe (F);
a volumetric circulation velocity setting unit (29r) that sets the volumetric velocity of the circulating refrigerant of the refrigeration cycle, which includes at least a compression mechanism (21), a refrigerant cooler (41), an expansion mechanism (24), and a refrigerant heater (23) ; and
a control unit (11) that controls the magnetic field at the outlet and with an increase in the volumetric velocity of the circulating refrigerant set by the volumetric flow rate determining unit (29r), performs at least one process selected from the group consisting of generating the magnetic field by the magnetic field generating unit (68), increasing the magnetic field generated by the magnetic field generating unit (68), and increasing the upper limit of the magnetic field generated by the magnet generating unit (68) total field. 2. Air conditioning (1) according to claim 1, in which the node (68) generating a magnetic field generates a magnetic field for induction heating of at least one element selected from the group consisting of a suction pipe (F) of refrigerant, which is a pipe refrigerant on the low pressure side of the compression mechanism (21), and an element in thermal contact with the refrigerant flowing through the refrigerant suction pipe (F). 3. The air conditioner (1) according to claim 1, in which the unit (29r) for establishing the volumetric circulation velocity performs its installation based on at least a predetermined working volume of the cylinder of the compression mechanism (21) specifying the frequencies of the compression mechanism (21) and refrigerant absorbed by the compression mechanism (21). 4. The air conditioner (1) according to claim 3, further comprising a low pressure setting unit (29g) that sets the pressure of the refrigerant flowing in the low pressure portion of the refrigeration cycle; and a unit (19) for setting the temperature of the suction refrigerant, which sets the temperature of the refrigerant sucked in by the compression mechanism (21); moreover, the volumetric circulation velocity setting unit (29r) obtains the density of the refrigerant absorbed by the compression mechanism (21) based on the pressure set by the low pressure setting unit (29g) and the temperature set by the suctioned refrigerant temperature setting unit (19). 5. Air conditioning (1) according to claim 4, in which the unit (19) for determining the temperature of the suctioned refrigerant is on the low pressure side of the compression mechanism (21) in the refrigeration cycle and registers the quantitative parameter of the refrigerant passing on the discharge side of the section subjected to induction heating by the unit (68) magnetic field generation. 6. Air conditioning (1) according to claim 4, in which the control unit (11) controls the output magnetic field in each case selected from the group consisting of the case in which the suction refrigerant of the compression mechanism (21) is in a wet state, and a case in which the suction refrigerant of the compression mechanism (21) is in an overheated state, the degree of overheating being less than a predetermined degree of overheating. 7. The air conditioner (1) according to any one of claims 1 to 6, in which the control unit (11) controls the output magnetic field if the volumetric speed of the circulating refrigerant set by the volumetric volumetric speed setting unit (29r) exceeds a predetermined value.

Images