JP2011032916A - Control valve - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To simply and inexpensively provide a filter structure in a control valve. <P>SOLUTION: In the control valve 1, a groove-like fitting part by body forming members 51, 52 is formed in a position including a port 11 introducing a high pressure discharge refrigerant, and a filter 12 is fit in the fitting part. A groove-like fitting part by body forming members 52, 53 is formed in a position including a port 13 introducing a refrigerant from a crank chamber at starting of a compressor, and a filter 14 is fit in the fitting part. Due to such a configuration, cases for housing each filter are not required. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a control valve that introduces a working fluid from a high-pressure side, depressurizes it, and leads it to a low-pressure side.

  In general, a control valve that opens and closes an internal fluid passage is used in an apparatus that performs control using the pressure of a working fluid in order to control the flow of the working fluid. For example, a variable capacity compressor (also simply referred to as a “compressor”) capable of varying the refrigerant discharge capacity is used in an automotive air conditioner so that a constant cooling capacity is maintained regardless of the engine speed. There are some, and a solenoid-driven control valve is used to control the capacity of the compressor (see, for example, Patent Document 1).

  In this compressor, a piston for compression is connected to a swing plate attached to a rotary shaft that is driven to rotate by an engine, and the discharge amount of the refrigerant is changed by changing the stroke of the piston by changing the angle of the swing plate. adjust. The angle of the swing plate can be continuously changed by introducing a part of the discharged refrigerant into the sealed crank chamber and changing the balance of pressure applied to both surfaces of the piston. The control valve controls at least one of a refrigerant flow rate introduced from the discharge chamber into the crank chamber and a refrigerant flow rate led out from the crank chamber to the suction chamber to change the discharge capacity of the compressor.

JP 2001-349278 A

  By the way, since such a compressor has many sliding parts, such as a piston, foreign materials, such as metal powder, generate | occur | produces by the abrasion in operation | movement, and may circulate through a refrigerating cycle in the form contained in a refrigerant | coolant. For this reason, the control valve is generally provided with a strainer at the introduction port on the high-pressure side to prevent foreign substances from entering. The strainer is generally provided in a form in which a filter is housed in a cylindrical case made of resin or metal, and is fitted into a portion of the control valve body where the introduction port is located. However, since the strainer is provided as a single component and assembled to the control valve in this way, there is room for improvement in terms of increasing the component cost.

  This invention is made | formed in view of such a subject, and it aims at providing the filter structure in a control valve simply and at low cost.

  A control valve according to an aspect of the present invention is provided in a fluid passage, and a body in which an introduction port into which a working fluid is introduced, a lead-out port from which the working fluid is led out, and a fluid passage that connects the introduction port and the lead-out port are formed. And a filter that is disposed in the introduction port and restricts the inflow of foreign matter into the body. This control valve is provided so as to cover a groove-like fitting portion provided at a position including the introduction port on the outer peripheral portion of the body and at least both ends in the width direction of the fitting portion from the outside. And a locking portion that forms an opening at the included position. The filter is made of an annular member having a larger width than the opening of the locking portion, and is fitted to the fitting portion and attached to the body so as to be locked to the locking portion from the outside. .

  According to this aspect, the groove-shaped fitting portion is provided in the body of the control valve, and the annular filter is fitted into the fitting portion so as to get over the locking portion. Since the filter itself can be deformed, there is no problem in fitting in the fitting portion. Further, after the filter is fitted, the locking portion prevents the dropout, so that the stability is also excellent. According to this aspect, the case for housing the filter is not required, and the filter structure can be realized simply and at low cost because the filter is directly attached to the body of the control valve.

  ADVANTAGE OF THE INVENTION According to this invention, the filter structure in a control valve can be provided simply and at low cost.

It is sectional drawing which shows the structure of the control valve which concerns on 1st Embodiment. It is a partial expanded sectional view corresponding to the upper half part of FIG. It is a figure showing operation | movement of a control valve. It is a figure showing operation | movement of a control valve. It is a figure which shows roughly the characteristic part of the assembly | attachment process and attachment process of a control valve. It is sectional drawing which shows the structure of the control valve which concerns on 2nd Embodiment. It is a partial expanded sectional view corresponding to the upper half part of FIG. It is a figure showing operation | movement of a control valve. It is a figure showing operation | movement of a control valve.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the following description, for the sake of convenience, the positional relationship between the structures may be expressed as upper and lower with reference to the illustrated state.

[First Embodiment]
FIG. 1 is a cross-sectional view showing a configuration of a control valve according to the first embodiment.
The control valve 1 of the present embodiment is configured as a control valve (solenoid valve) that controls a variable capacity compressor (not shown) (simply referred to as “compressor”) installed in a refrigeration cycle of an automotive air conditioner. This compressor compresses the refrigerant flowing through the refrigeration cycle and discharges it as a high-temperature and high-pressure gas refrigerant. The gas refrigerant is condensed in a condenser (external heat exchanger) and further adiabatically expanded by an expansion device to become a low temperature / low pressure mist refrigerant. The low-temperature and low-pressure refrigerant evaporates in the evaporator, and the passenger compartment air is cooled by the latent heat of vaporization. The refrigerant evaporated in the evaporator is returned again to the compressor and circulates in the refrigeration cycle. In the compressor, a piston for compression is connected to a rocking plate attached to a rotating shaft that is rotationally driven by an automobile engine, and the amount of refrigerant discharged is changed by changing the stroke of the piston by changing the angle of the rocking plate. Adjust. The control valve 1 controls the flow rate of the refrigerant introduced from the discharge chamber of the compressor into the crank chamber, thereby changing the angle of the swing plate, and hence the discharge capacity of the compressor.

  The control valve 1 is configured as a so-called Ps sensing valve that controls the flow rate of refrigerant introduced from the discharge chamber into the crank chamber so as to keep the suction pressure Ps of the compressor at a set pressure. The control valve 1 includes a valve body 2 including a valve portion that opens and closes a refrigerant passage for introducing a part of the discharged refrigerant into the crank chamber, and a refrigerant flow rate that is introduced into the crank chamber by adjusting the opening of the valve portion. The solenoid 3 to be controlled is integrally assembled. The valve body 2 includes a stepped cylindrical body 5, a valve portion provided inside the body 5, and a power element 4 (“sensation” provided inside the body 5 for generating a driving force for opening and closing the valve portion. Corresponding to “pressure part”). The body 5 and the solenoid 3 are connected and fixed via a connecting member 6.

  A port 11 (corresponding to a “discharge chamber communication port”) that receives the discharge pressure Pd in communication with the discharge chamber of the compressor is provided on the side of the body 5. A filter 12 is attached to the port 11 for suppressing entry of dust and the like into the body 5. The port 11 communicates internally with a port 13 (corresponding to a “crank chamber communication port”) provided in the upper portion of the body 5. The port 13 is also provided with a filter 14 for suppressing entry of dust and the like into the body 5. The port 13 communicates with the crank chamber of the compressor and guides the refrigerant passing through the main valve toward the crank chamber, while introducing the refrigerant discharged from the crank chamber when the compressor is started. The refrigerant introduced at this time is led out to the suction chamber through the auxiliary valve. A lower end opening of the body 5 communicates with a suction chamber of the compressor through a space formed between the body 3 and the solenoid 3.

  A stepped cylindrical valve forming member 15 is provided in the refrigerant passage communicating with the port 11 and the port 13 so as to be displaceable in the axial direction, and a valve hole 16 is formed by the internal passage. The diameter of the valve forming member 15 is increased at the lower end opening of the valve hole 16, and a valve seat 17 (main valve seat) is formed by the base end portion of the expanded diameter portion. And the valve body 18 (main valve body) is arrange | positioned so as to oppose the valve seat 17 from the port 11 side so that contact / separation is possible. The valve body 18 is formed as a part of a stepped cylindrical actuating rod 19. The actuating rod 19 moves in the axial direction by being guided while sliding along the inner peripheral surface of the body 5. The valve seat 17 has a tapered surface, and the outer peripheral edge of the valve body 18 is attached to and detached from the valve seat 17 to open and close the main valve (first valve portion), thereby adjusting the flow rate of refrigerant flowing from the discharge chamber to the crank chamber. To do. A valve seat 20 (sub valve seat) is formed slightly above the port 13 in the body 5. On the other hand, the upper end portion of the valve forming member 15 is provided with a flange portion extending outward in the radial direction, and a valve body 21 (sub-valve body) is formed by the flange portion. The valve body 21 is attached to and detached from the valve seat 20 from above to open and close the auxiliary valve (second valve portion), and adjust the flow rate of the refrigerant relieved from the crank chamber to the suction chamber.

  The inner diameter of the lower end opening of the body 5 is expanded downward, and a disc-shaped stopper 23 is press-fitted. An insertion hole 24 is provided at the center of the stopper 23, and the lower end of the operating rod 19 is inserted. The connecting member 6 has a bottomed cylindrical shape, is press-fitted into the upper half of the connecting member 6 so that the lower end of the body 5 is inserted therein, and the solenoid 3 is connected to the bottom. A port 26 (corresponding to a “suction chamber communication port”) that communicates with the suction chamber of the compressor and receives the suction pressure Ps is formed on the side of the connection member 6. An internal space surrounded by the body 5, the connection member 6, and the solenoid 3 forms a pressure chamber 28 into which the suction pressure Ps is introduced. In the pressure chamber 28, a power element 4 (corresponding to a “pressure-sensitive portion”) that operates in the axial direction by detecting the suction pressure Ps is disposed.

  On the other hand, the solenoid 3 has a bottomed cylindrical case 30 that also functions as a yoke, a bottomed cylindrical sleeve 31 fixed to the case 30, and an opening side of the sleeve 31 that is fixed to the case 30. A cylindrical core 32 inserted in the upper half, and a cylindrical plunger 33 accommodated in the lower half on the bottom side of the sleeve 31 and arranged to face the core 32 in the axial direction; The electromagnetic coil 34 which produces | generates a magnetic circuit with the supplied electric current, and the edge part member 35 provided so that the lower end opening part of the case 30 might be sealed. The bottom of the connection member 6 and the bottom of the case 30 are abutted with each other, and an insertion hole 29 is formed so as to penetrate the center of the bottom. Then, the upper end portion of the core 32 is inserted into the insertion hole 29 and crimped outward, thereby connecting and fixing the connecting member 6 and the case 30 so as to be sandwiched from the inside.

  A cylindrical shaft 36 is inserted so as to penetrate the center of the core 32 in the axial direction. The lower end of the shaft 36 is press-fitted coaxially with the upper end of the plunger 33. As a result, the shaft 36 and the plunger 33 are fixed, and an internal passage 37 penetrating both in the axial direction is formed. The upper end of the shaft 36 is connected to the power element 4, and transmits the solenoid force to the operating rod 19 through the power element 4. In the present embodiment, the shaft 36 is formed by rounding a rectangular stainless steel plate into a tubular shape by pressing, and is configured to leave a gap of a predetermined width without joining both ends in the rounding direction. Yes. That is, a slit 38 that is parallel to the axial line is formed on one side of the shaft 36 to communicate the inside and outside. For this reason, the suction pressure Ps in the pressure chamber 28 is introduced into the shaft 36 through the slit 38 and guided to the back pressure chamber 39 of the plunger 33 through the shaft 36 and the internal passage 37 of the plunger 33. In the modified example, a slit for communicating the inside and the outside may be formed in a part of the longitudinal direction of the shaft 36, and the suction pressure Ps in the pressure chamber 28 may be introduced from the slit.

  The sleeve 31 is made of a nonmagnetic material, and the bottom center portion thereof is slightly convex upward so that the plunger 33 can be supported from below. Further, a cylindrical bobbin 41 is extrapolated to the sleeve 31, and an electromagnetic coil 34 is wound around the bobbin 41. A seal ring 47 is interposed in a space surrounded by the outer peripheral surface of the upper end portion of the core 32, the upper end surface of the sleeve 31, and the inner surface of the bottom portion of the case 30, thereby securing a seal inside and outside the solenoid 3.

  The lower end portion of the case 30 is enlarged in diameter to form an enlarged diameter portion 40 protruding outward in the radial direction, and a disk-like collar 42 is disposed on the inside thereof. The collar 42 is fixed to the case 30 by crimping the lower end portion of the enlarged diameter portion 40 inward. The collar 42 is made of a magnetic material and constitutes a magnetic circuit together with the case 30. An insertion hole 43 is provided at the center of the bottom of the collar 42, and the lower end of the sleeve 31 is exposed through the insertion hole 43. A pair of connection terminals 44 connected to the electromagnetic coil 34 extend from the bobbin 41 and extend through the collar 42 and the end member 35 to the outside. For convenience of explanation, only one of the pair is displayed in the figure.

  The end member 35 is attached so as to seal the entire structure in the solenoid 3 included in the case 30 from below. The end member 35 is formed by molding a resin material having corrosion resistance (in this embodiment, injection molding), and the resin material is also filled in the gap between the case 30 and the electromagnetic coil 34. As described above, the resin material fills the gap between the case 30 and the electromagnetic coil 34 to facilitate the transfer of heat generated in the electromagnetic coil 34 to the case 30 and to improve the heat dissipation performance. In addition, the specific method of this resin mold is mentioned later. The end portion of the connection terminal 44 is drawn out from the end member 35 and is connected to an external power source (not shown). In addition, as a resin material which forms the edge part member 35, what has moderate hardness and elasticity like 66 nylon etc. containing glass, for example is preferable. In order to ensure a certain level of mounting accuracy, it is preferable that the hardness is higher than that of rubber.

  The end member 35 extends so as to overlap the outer peripheral surface of the case 30 by a predetermined length so as to get over the enlarged diameter portion 40 from the lower end opening side of the case 30. Further, as described above, the end member 35 is also filled inward of the case 30 and extends to the upper end portion of the bobbin 41, so that the end member 35 is reliably prevented from falling off the case 30. Has been. In addition, since the overlap portion of the end member 35 is formed at the lower end portion of the case 30, a seal structure that suppresses entry of the refrigerant into the case 30 is realized at the same time.

  However, in the present embodiment, a relatively small O-ring 48 is interposed between the upper end opening of the end member 35 and the side surface of the case 30 in order to ensure the sealing action. Further, an O-ring 49 is attached above the end member 35 so as to be extrapolated to the case 30. The O-ring 49 is larger than the O-ring 48 and is interposed between the mounting hole and the case 30 when the control valve 1 is mounted in a mounting hole provided in a compressor housing (not shown). And restricts the entry of foreign matter from the outside into the housing. In the modification, the O-ring 48 may be omitted. In that case, it is not necessary to provide a groove for fitting and accommodating the O-ring 48 at the tip of the end member 35.

FIG. 2 is a partially enlarged cross-sectional view corresponding to the upper half of FIG.
The body 5 is formed by sequentially fitting a plurality of cylindrical body forming members obtained by press forming a stainless steel plate and connecting them in the axial direction. That is, the body 5 is formed by fitting the body forming member 51 so that the body forming member 52 is inserted, and further fitting the body forming member 53 to the double pipe structure. The body forming member 51 has a stepped cylindrical shape with a diameter decreasing upward, and is press-fitted so that the lower half of the large diameter portion is inserted into the upper half of the connecting member 6. A communication hole 55 is provided in the middle diameter portion of the body forming member 51 to communicate the inside and outside.

  The body forming member 52 has a stepped cylindrical shape whose diameter is increased upward, and its middle diameter portion is press-fitted into the small diameter portion of the body forming member 51, and the large diameter portion is substantially the same as the small diameter portion of the body forming member 51. Has an outer diameter. The small-diameter portion of the body forming member 52 has an outer diameter that is substantially the same as the inner diameter of the insertion hole 24 of the stopper 23, and the distal end portion extends through the insertion hole 24 to the pressure chamber 28. A valve seat 20 is formed on the upper surface of the base end portion of the large diameter portion of the body forming member 52. In addition, a communication hole 56 that forms the port 11 together with the communication hole 55 is provided at a position corresponding to the communication hole 55 in the medium diameter portion of the body forming member 52. An O-ring 61 for sealing is interposed in a space surrounded by the body forming member 51, the body forming member 52, and the stopper 23.

  In the vicinity of the large-diameter portion of the medium-diameter portion of the body forming member 52, a communication hole 57 that communicates the inside and the outside is provided. The body forming member 53 has a bottomed cylindrical shape, and the bottom thereof is press-fitted so as to cover the upper end opening of the body forming member 52. The body forming member 53 extends to a position where its lower end opening overlaps with the upper end of the body forming member 51, and the position corresponding to the communication hole 57 in the lower end is communicated by connecting the inside and the outside. A communication hole 58 that forms the port 13 together with the hole 57 is provided. In the present embodiment, body forming member 51 and body forming member 52 constitute a “first body”, and body forming member 53 constitutes a “second body”.

  The filter 12 is disposed in a space surrounded by the lower end surface of the small diameter portion of the body forming member 51, the lower outer peripheral surface of the medium diameter portion of the body forming member 52, the O-ring 61, and the inner peripheral surface of the body forming member 51. ing. That is, a groove-shaped fitting portion 59 is formed by the lower end surface of the small diameter portion of the body forming member 51, the lower outer peripheral surface of the medium diameter portion of the body forming member 52, and the O-ring 61. An annular filter 12 is fitted. And the body formation member 51 is arrange | positioned so that the fitting part 59 may be covered from the outside. That is, the filter 12 is disposed in a space between the body forming member 51 and the body forming member 52 so as to be able to be locked from inside and outside, and the drop-off is reliably prevented. The filter 12 is formed in an annular shape by rounding a long band-shaped metal mesh in the longitudinal direction so that both ends thereof overlap each other by a predetermined amount, and spot welding is performed on the overlap portion. Since the filter 12 has a larger width than the communication holes 55 and 56 as shown in the drawing, a part of the filter 12 does not come out of the communication hole 55 or the communication hole 56.

  On the other hand, the upper end surface of the small diameter portion of the body forming member 51, the upper outer peripheral surface of the medium diameter portion of the body forming member 52, the lower end surface of the large diameter portion of the body forming member 52, and the lower end portion of the body forming member 53 The filter 14 is disposed in a space surrounded by the peripheral surface. That is, the groove-shaped fitting portion 60 is formed by the upper end surface of the small diameter portion of the body forming member 51, the upper outer peripheral surface of the medium diameter portion of the body forming member 52, and the lower end surface of the large diameter portion of the body forming member 52. The annular filter 14 is fitted to the fitting portion 60. And the body formation member 53 is assembled | attached so that the fitting part 60 may be covered from the outside. That is, the filter 14 is disposed in a space between the body forming member 52 and the body forming member 53 so as to be able to be locked from the inside and outside, and the dropout is reliably prevented. The filter 14 is formed in an annular shape by rounding a long band-shaped metal mesh in the longitudinal direction so that both ends thereof are overlapped by a predetermined amount and spot welding is applied to the overlap portion. Since the filter 14 has a larger width than the communication holes 57 and 58 as shown in the drawing, a part of the filter 14 does not come out of the communication hole 57 or outward of the communication hole 58.

  The valve forming member 15 is formed by joining a cylindrical valve body forming member 63 and a valve seat forming member 64 obtained by press forming a stainless steel plate at the ends and connecting them in the axial direction. Yes. The valve body forming member 63 is provided with a communication hole 65 that communicates the inside and the outside at a position corresponding to the port 13 on the side thereof, and a flange portion that extends radially outward is provided at the upper end portion. The flange part forms the valve body 21, and attaches and detaches to the valve seat 20 from above to open and close the sub valve. Further, the upper half of the valve body forming member 63 is slightly enlarged in diameter, and forms a sliding portion of the operating rod 19. On the other hand, the valve seat forming member 64 forms the valve hole 16 in the upper half of the valve seat, and its upper end is press-fitted into the lower end of the valve body forming member 63. The lower half of the valve seat forming member 64 has an enlarged diameter, and a communication hole 66 is provided at the position corresponding to the port 11 on the side of the valve seat forming member 64 to communicate the inside and outside. The valve seat 17 is formed at the proximal end portion of the enlarged diameter portion. A ring-shaped stopper 67 is press-fitted between the communication hole 56 and the communication hole 57 of the body forming member 52 and is surrounded by the body forming member 52, the stopper 67 and the valve seat forming member 64. A sealing O-ring 68 is disposed in the space. The O-ring 68 restricts the high-pressure refrigerant introduced from the port 11 from flowing to the port 13 side through the gap between the valve forming member 15 and the body forming member 52.

  The operating rod 19 is formed by connecting the valve body forming member 71 and the guide member 72 in the axial direction. The valve body forming member 71 has a cylindrical shape obtained by cutting a stainless steel material, and the lower half of the valve body forming member 71 is slidably inserted into the guide hole 25 formed in the small diameter portion of the body forming member 52. Yes. In addition, a plurality of legs 73 projecting outward in the radial direction are provided on the side of the valve body forming member 71 and are slidably supported on the lower half of the valve seat forming member 64. The valve body 18 is formed by an upper end portion of the valve seat forming member 64, and is attached to and detached from the valve seat 17 from below to open and close the main valve.

  The guide member 72 has a stepped cylindrical shape obtained by press-molding a stainless steel plate, and is press-fitted so that the lower end portion thereof is inserted into the upper half portion of the valve body forming member 71. The inner diameter of the upper half part of the valve body forming member 71 is increased, and when the guide member 72 is connected, the inner diameter of the connecting part is made equal. The guide member 72 penetrates the valve seat forming member 64 with a predetermined gap, and its upper end portion is enlarged in two stages. The first-stage enlarged diameter portion is supported by the valve body forming member 63 so as to be slidable in the axial direction, and a communication hole 74 that communicates the inside and the outside is provided at a slightly upper side portion of the sliding portion. The second-stage enlarged diameter portion is supported by the large-diameter portion of the body forming member 52 so as to be slidable in the axial direction.

  Between the guide member 72 and the body forming member 53, a spring 75 for biasing the operating rod 19 in the valve opening direction of the main valve is interposed. A spring 76 that biases the valve forming member 15 in the valve closing direction of the sub valve is interposed between the guide member 72 and the valve body forming member 63. The load of the spring 76 is set smaller than the load of the spring 75. The pressure chamber 77 surrounded by the valve body forming member 63, the guide member 72 and the body forming member 53 communicates with the pressure chamber 28 via the internal passage 78 of the operating rod 19. That is, the pressure chamber 77 is filled with the suction pressure Ps as in the pressure chamber 28.

  In the modification, a seal member may be provided between the body forming member 52 and the valve body forming member 71 to restrict the discharge refrigerant introduced from the port 11 from leaking into the pressure chamber 28. For example, a thin film sheet-shaped (ring-shaped) packing may be provided at the base end of the small diameter portion of the body forming member 52. You may comprise so that the inner peripheral part may crimp | bond to the sliding surface of the valve body formation member 71 by a self-sealing effect | action when a differential pressure acts on the packing.

  The power element 4 forms a hollow housing 81 interposed between the actuating rod 19 and the shaft 36 and supported so as to be displaceable in the valve opening / closing direction, and a reference pressure chamber S sealed in the housing 81. And a reaction force transmission member 69 connected to the upper end of the pressure-sensitive member 82. The housing 81 is formed by joining a first housing 84 and a second housing 85 obtained by press-molding a stainless steel plate, and forms a housing space for the pressure-sensitive member 82 and the reaction force transmission member 69 therein.

  The first housing 84 has a bottomed cylindrical shape, and is provided with three leg portions 86 extending downward at the center of the bottom portion (only one of them is shown in the figure). The upper end portion of the shaft 36 is accommodated in the space surrounded by the three leg portions 86 and is connected to the shaft 36. Each leg portion 86 is obtained by making a cut in the bottom portion of the first housing 84 and bending the cut portion downward. As a result of forming the leg portion 86 in this way, three communication holes 87 are formed in the bottom portion of the first housing 84 to communicate the inside and the outside. The position surrounded by the three leg portions 86 at the center of the bottom portion of the first housing 84 is formed in a concave shape so as to fit the center of the lower end of the pressure-sensitive member 82. A plurality of insertion holes 88 are provided in the upper half side of the first housing 84 so as to communicate the inside and outside and expose a part of the reaction force transmission member 69.

  The second housing 85 has a bottomed cylindrical shape, and is joined (welded) to the first housing 84 at the tip of a flange portion extending radially outward at the upper end portion thereof. The second housing 85 is slidably supported by being inserted into the small diameter portion of the pressure-sensitive member 82, and supports the operating rod 19 from below at the bottom thereof. A communication hole 89 is provided in the center of the bottom of the second housing 85 to allow communication between the inside and the outside. Through this communication hole 89, the internal passage 78 of the operating rod 19 and the housing space of the housing 81 are communicated. A plurality of insertion holes 90 for exposing a part of the reaction force transmission member 69 are provided at positions corresponding to the plurality of insertion holes 88 on the outer periphery of the upper end of the second housing 85.

  The pressure-sensitive member 82 includes a pair of diaphragms 91 and 92 facing vertically (the opening and closing direction of the valve portion), a pair of stopper members 93 and 94 joined to the pair of diaphragms, and a pair of stopper members It includes a spring 95 interposed therebetween. The diaphragms 91 and 92 both have a bottomed cylindrical main body obtained by press-molding a thin-film metal diaphragm, and are joined so as to abut the opening to form a reference pressure chamber S. That is, by performing outer periphery welding in a state where the outer peripheral edge portions extending radially outward are abutted with each other at the opening end portions of the diaphragms, and the outer peripheral edge portions are sandwiched and sealed by the pair of ring members 96 and 97. A sealed reference pressure chamber S is formed. Since this welding is performed in a vacuum atmosphere, the reference pressure chamber S is in a vacuum state, but the reference pressure chamber S may be filled with air or the like. The pair of ring members 96 and 97 have the same outer diameter, and also function as guide members that are guided while sliding on the inner peripheral surface of the first housing 84. A connecting portion that protrudes upward is formed at the center of the bottom of the diaphragm 91, and a connecting portion that protrudes downward is formed at the center of the bottom of the diaphragm 92.

  The stopper member 93 has a stepped columnar shape and is connected so that a convex portion 98 protruding from the center of the upper surface thereof is fitted to the connecting portion of the diaphragm 91 from below. A flange portion 45 extending outward in the radial direction is provided on a side portion of the stopper member 93. On the other hand, the stopper member 94 also has a stepped columnar shape, and a convex portion 99 protruding from the center of the lower surface thereof is connected to the connecting portion of the diaphragm 92 so as to be fitted from above. That is, the connecting portion of the diaphragm 92 is fixed so as to be sandwiched between the concave shape at the center of the bottom portion of the first housing 84 and the convex portion 99 of the stopper member 94. A flange portion 46 extending outward in the radial direction is provided on a side portion of the stopper member 94. The spring 95 is interposed between the flange portion 45 and the flange portion 46 and urges the stopper member 93 and the stopper member 94 in a direction in which they are separated from each other. For this reason, the pressure-sensitive member 82 expands or contracts in the axial direction (the opening and closing direction of the valve portion) according to the differential pressure between the suction pressure Ps of the pressure chamber 28 and the reference pressure of the reference pressure chamber S. However, even if the differential pressure increases, if the pressure-sensitive member 82 contracts by a predetermined amount, the distal end surfaces of the stopper member 93 and the stopper member 94 come into contact with each other and are locked, so that the contraction is restricted.

  The reaction force transmission member 69 has a disc shape and has three leg portions 70 extending from the outer peripheral edge portion thereof through the housing 81 and extending upward (only one is shown in the figure). The center position of the reaction force transmission member 69 is formed in a concave shape so as to fit the center of the upper end of the pressure sensitive member 82. In other words, the connecting portion of the diaphragm 91 is fixed between the concave shape and the convex portion 98 of the stopper member 93. A spring 79 is interposed between the reaction force transmission member 69 and the second housing 85 to urge them in the direction of separating them. Although the reaction force transmission member 69 may come into contact with the bottom of the second housing 85 due to the extension of the pressure-sensitive member 82, the bottom of the second housing 85 has a wave shape as shown in the figure. Therefore, the communication state between the internal passage 78 of the operating rod 19 and the housing space of the housing 81 is maintained.

  In such a configuration, when the suction pressure Ps in the pressure chamber 28 becomes lower than a predetermined set pressure Pset, the pressure-sensitive member 82 is deformed in the extending direction, and the leg portion 70 of the reaction force transmitting member 69 moves on the lower surface of the stopper 23. Press. As a result, a reaction force acting on the reaction force transmission member 69 is transmitted to the shaft 36 via the pressure-sensitive member 82 and the housing 81, and a force in a direction to reduce the solenoid force by the solenoid 3 acts. . This set pressure Pset is basically adjusted in advance by the spring load of the spring 95, and is set as a pressure value that can prevent freezing of the evaporator from the relationship between the temperature in the evaporator and the suction pressure Ps. The set pressure Pset can be changed by changing the supply current (set current) to the solenoid 3.

  In the present embodiment, the effective pressure receiving diameter A of the main valve (the inner diameter of the open end of the valve hole 16), the inner diameter B of the guide hole 25, and the sliding portion of the guide member 72 with the valve body forming member 63 The outer diameter C (= the inner diameter of the enlarged portion of the valve body forming member 63) is formed substantially equal. Accordingly, the force due to the discharge pressure Pd acting on the operating rod 19, the force due to the crank pressure Pc, and the force due to the suction pressure Ps are all cancelled. For this reason, in the control state of the compressor, the valve element 18 opens and closes based on the solenoid force in the valve closing direction by the solenoid 3, the force in the valve opening direction by the spring 75, and the reaction force in the valve opening direction by the power element 4. Will work. On the other hand, the outer diameter A2 (= the inner diameter of the O-ring 68) of the lower sliding portion of the valve seat forming member 64 is formed smaller than the effective pressure receiving diameter A of the main valve by a predetermined amount. Therefore, the discharge pressure Pd introduced from the port 11 acts on the valve seat forming member 64 and thus the valve forming member 15 in the valve closing direction of the sub valve. For this reason, even if the load of the spring 76 is small, the closed state of the auxiliary valve can be maintained in the steady control state of the control valve 1. However, the difference between the effective pressure receiving diameter A and the outer diameter A2 is set to such an extent that the smooth opening of the auxiliary valve is not hindered when the control valve 1 is activated (when the activation current is supplied to the solenoid 3). On the other hand, a differential pressure (Pc-Ps) between the crank pressure Pc and the suction pressure Ps acts on the valve forming member 15 in the valve body forming member 63, and the differential pressure (Pc-Ps) is a normal control. It is so small that there is no problem in the state. For this reason, in the control state of the compressor, the state where the valve element 21 is seated on the valve seat 20 by the urging force of the spring 76 (the closed state of the sub valve) is maintained. In the configuration in which the closed state of the sub valve in the steady control state of the control valve 1 can be ensured by using the discharge pressure Pd or the like as described above, the spring 76 can be omitted.

Next, the operation of the control valve will be described.
3 and 4 are diagrams showing the operation of the control valve, and correspond to FIG. FIG. 2 which has already been described shows the maximum capacity operation state of the control valve. FIG. 3 shows a state when the bleed function of the control valve is operated. FIG. 4 shows a relatively stable control state. In the following, description will be given based on FIG. 1 and with reference to FIGS.

  In the control valve 1, when the solenoid 3 is not energized, that is, when the automotive air conditioner is not operating, no suction force acts between the core 32 and the plunger 33. Further, since the spring 75 urges the shaft 36 downward via the operating rod 19 and the power element 4, the valve body 18 is separated from the valve seat 17 and the main valve is fully opened. On the other hand, the state in which the valve body 21 is seated on the valve seat 20 is maintained by the urging force of the spring 76, so that the sub-valve is closed. At this time, the refrigerant having the discharge pressure Pd introduced from the discharge chamber of the compressor into the port 11 passes through the fully opened main valve and flows from the port 13 to the crank chamber. Therefore, the crank pressure Pc is increased and the compressor is operated at the minimum capacity. In this case, since the suction pressure Ps is relatively high, the pressure-sensitive member 82 is contracted. At this time, since the leg portion 70 is separated from the stopper 23, the power element 4 is interposed between the operating rod 19 and the shaft 36, but does not substantially function.

  On the other hand, when the maximum control current is supplied to the electromagnetic coil 34 of the solenoid 3, such as when the automobile air conditioner is started, the plunger 33 is attracted to the core 32 with the maximum suction force. At this time, as shown in FIG. 3, the solenoid force is transmitted as it is to the operating rod 19 via the power element 4 and the valve body 18 is seated on the valve seat 17, but the main valve only closes because the solenoid force is large. However, the operating rod 19 is further raised while pressing the valve forming member 15. As a result, the valve body 21 is separated from the valve seat 20 and the auxiliary valve is opened. At this time, the pressure-sensitive member 82 contracts to the minimum state where the stopper member 93 and the stopper member 94 abut, and the power element 4 is displaced to its top dead center.

  That is, by supplying a starting current to the solenoid 3, the main valve is closed to restrict the introduction of the refrigerant discharged into the crank chamber, and at the same time, the valve forming member 15 is displaced, and the auxiliary valve is immediately opened to draw the refrigerant in the crank chamber into the suction chamber. Relieve promptly. In the present embodiment, the crank chamber is depressurized through a depressurization passage (an orifice or the like connecting the crank chamber and the suction chamber) formed in the compressor. In this way, the subvalve is opened quickly. Thus, the pressure reduction responsiveness can be maximized, and the compressor can be started quickly. If the control current supplied to the solenoid 3 is slightly reduced from this state, as shown in FIG. 2, a maximum capacity operation state in which both the main valve and the subvalve are closed is obtained.

  Here, when the current value supplied to the solenoid 3 is in the control state set to a predetermined value, as shown in FIG. 4, the valve body 21 is seated on the valve seat 20 and the subvalve is closed. The valve body 18 operates separately from the valve body 21 to open and close the main valve. At this time, the valve body 18 is a solenoid by the power element 4 operated by the force in the valve opening direction by the spring 75, the force in the valve closing direction by the spring 76, the solenoid force in the valve closing direction by the solenoid 3, and the suction pressure Ps. Stops at the valve lift position where the force in the direction to reduce the force is balanced.

  For example, when the refrigeration load increases and the suction pressure Ps becomes higher than the set pressure Pset, the pressure-sensitive member 82 is reduced, so that the power element 4 and thus the valve body 18 is displaced relatively upward (in the valve closing direction). As a result, the valve opening of the main valve decreases, and the compressor operates to increase the discharge capacity. As a result, the suction pressure Ps changes in a decreasing direction. Conversely, when the refrigeration load is reduced and the suction pressure Ps is lower than the set pressure Pset, the pressure-sensitive member 82 extends. As a result, the reaction force of the reaction force transmission member 69 acts on the shaft 36 in the direction of reducing the solenoid force. As a result, the force in the valve closing direction on the valve body 18 is reduced, the valve opening of the main valve is increased, and the compressor operates to reduce the discharge capacity. As a result, the suction pressure Ps is maintained at the set pressure Pset, and excessive cooling is prevented.

FIG. 5 is a diagram schematically showing a characteristic part of the assembly process and the installation process of the control valve. (A) and (B) represent the assembly process. (C) represents a state when the control valve is attached to the compressor.
When assembling the control valve 1, first, as shown in FIG. 3A, the core 32, the plunger 33 and the shaft 36 accommodated in the sleeve 31, the bobbin 41 around which the electromagnetic coil 34 is wound, the connection A solenoid assembly including a terminal 44 and a collar 42 is assembled. At this time, the connecting member 6 is also assembled. Thereafter, the solenoid assembly is incorporated into a mold (not shown) and a resin material is molded (injection molding) to integrally mold the end member 35 as shown in FIG. During the molding process, the gap between the case 30 and the electromagnetic coil 34 is also filled with the resin material. Thereafter, as shown in FIG. 5C, the control valve 1 is configured by assembling the valve body 2 to the connecting member 6.

  The control valve 1 assembled in this way is attached to an attachment hole 100 provided in the housing of the compressor, as shown in FIG. At this time, the control valve 1 is inserted into the mounting hole 100 from the valve body 2 side, and is fixed by a washer or the like (not shown). Since the O-ring 49 is interposed between the case 30 and the mounting hole 100, it is effectively prevented or suppressed that the external atmosphere enters the inside of the mounting hole 100.

  As described above, in the control valve 1 of the present embodiment, the groove-shaped fitting portion is formed by the body forming members 51 and 52 at the position including the port 11 into which the high-pressure discharged refrigerant is introduced. The filter 12 is fitted into the fitting portion. Further, when the compressor is started, a groove-like fitting portion is formed by the body forming members 52 and 53 at a position including the port 13 into which the refrigerant from the crank chamber is introduced, and a filter is formed in the fitting portion. 14 is fitted. With such a configuration, a case for accommodating each filter becomes unnecessary. Further, since the filter is directly attached to the body 5, the filter structure can be realized simply and at low cost.

  Further, the operating rod 19 and the shaft 36 are rigidly connected via the housing 81 without using an elastic member or the like, and the solenoid force is transmitted as it is to the valve body 18 of the main valve. For this reason, when the solenoid 3 is switched from OFF to ON and a starting current is supplied, the main valve can be quickly closed. Further, the valve seat 17 of the main valve and the valve body 21 of the sub valve are formed integrally with the valve forming member 15, and the valve forming member 15 also functions as a movable valve seat. For this reason, since the main valve closes and the sub valve opens so that the introduction of the refrigerant into the crank chamber is restricted, the refrigerant can be discharged from the crank chamber and the compressor can be started quickly. it can. Further, since the actuating rod 19 is directly driven by the solenoid 3, even if foreign matter that has passed through the port 11 enters the gap between the body forming member 52 and the valve body forming member 71, When the operating rod 19 is largely displaced, the foreign matter can be scraped out from the gap. For this reason, even if a sealing member is not disposed at the entrance of the gap between the body forming member 52 and the valve body forming member 71, the occurrence of biting of foreign matter can be prevented or suppressed.

[Second Embodiment]
Next, a second embodiment of the present invention will be described. The control valve according to the present embodiment has a common part with the first embodiment although the valve opening structure of the sub-valve is different. For this reason, components that are substantially the same as those in the first embodiment are denoted by the same reference numerals. FIG. 6 is a cross-sectional view showing the configuration of the control valve according to the second embodiment.

FIG. 6 is a cross-sectional view showing the configuration of the control valve according to the second embodiment.
The control valve 101 of the present embodiment is configured as a control valve (solenoid valve) that controls a variable capacity compressor (not shown) (simply referred to as “compressor”) installed in the refrigeration cycle of the automotive air conditioner. This compressor compresses the refrigerant flowing through the refrigeration cycle and discharges it as a high-temperature and high-pressure gas refrigerant. The gas refrigerant is condensed in a condenser (external heat exchanger) and further adiabatically expanded by an expansion device to become a low temperature / low pressure mist refrigerant. The low-temperature and low-pressure refrigerant evaporates in the evaporator, and the passenger compartment air is cooled by the latent heat of vaporization. The refrigerant evaporated in the evaporator is returned again to the compressor and circulates in the refrigeration cycle. In the compressor, a piston for compression is connected to a rocking plate attached to a rotating shaft that is driven to rotate by an automobile engine, and the amount of refrigerant discharged is changed by changing the angle of the rocking plate to change the stroke of the piston. Adjust. The control valve 101 controls the flow rate of the refrigerant introduced from the discharge chamber of the compressor into the crank chamber, thereby changing the angle of the swing plate, and thus the discharge capacity of the compressor.

  The control valve 101 is configured as a so-called Ps sensing valve that controls the flow rate of refrigerant introduced from the discharge chamber into the crank chamber so as to keep the suction pressure Ps of the compressor at a set pressure. The control valve 101 includes a valve main body 102 including a valve portion that opens and closes a refrigerant passage for introducing a part of the discharged refrigerant into the crank chamber, and a flow rate of refrigerant introduced into the crank chamber by adjusting the opening of the valve portion. The solenoid 103 to be controlled is integrally assembled. The valve body 102 includes a stepped cylindrical body 105, a valve portion provided inside the body 105, a power element 104 ("sensation" provided inside the body 105 and generating a driving force for opening and closing the valve portion. Corresponding to “pressure part”). The body 105 and the solenoid 103 are connected and fixed via a connecting member 106. Note that a combination of the body 105 and the connection member 106 can be regarded as the body of the control valve 101.

  A port 11 (corresponding to a “discharge chamber communication port”) that receives the discharge pressure Pd in communication with the discharge chamber of the compressor is provided on a side portion of the body 105. A filter 12 is attached to the port 11 for suppressing entry of dust and the like into the body 105. The port 11 communicates internally with a port 13 (corresponding to a “crank chamber communication port”) provided in the upper portion of the body 105. The port 13 communicates with the crank chamber of the compressor and guides the refrigerant passing through the main valve toward the crank chamber, while introducing the refrigerant discharged from the crank chamber when the compressor is started. The refrigerant introduced at this time is led out to the suction chamber through the auxiliary valve. The lower end opening of the body 105 communicates with the suction chamber of the compressor through a space formed between the solenoid 103 and the lower end opening. A port 26 (corresponding to a “suction chamber communication port”) that communicates with the suction chamber of the compressor and receives the suction pressure Ps is formed on the side of the lower end portion of the body 105.

  A valve hole 16 is formed in a refrigerant passage (main passage) that connects the port 11 and the port 13 in the body 105, and a valve seat 17 (main valve seat) is provided at the opening end of the valve hole 16 on the port 11 side. Is formed. The body 105 is provided with a cylindrical valve forming member 115 that can be displaced in the axial direction. The upper end of the valve forming member 115 is reduced in diameter and inserted into the valve hole 16, and a valve element 18 (main valve element) is formed by the proximal end of the reduced diameter part. That is, the valve body 18 is formed as a part of the valve forming member 115 and is disposed so as to face the valve seat 17 so as to be able to contact and separate from the port 11 side. The internal passage of the valve forming member 115 forms a refrigerant passage (sub-passage) that connects the port 13 and the port 26.

  The valve forming member 115 has a sliding portion slidable in the insertion hole 24 provided in the center portion of the body 105 and a sliding portion slidable on the upper end portion of the valve hole 16. The part is guided to operate in the axial direction. The reduced diameter portion of the valve forming member 115 is provided with a communication hole 116 that communicates the inside and the outside. The valve seat 17 has a tapered surface, and the outer peripheral edge of the valve body 18 is attached to and detached from the valve seat 17 to open and close the main valve (first valve portion), thereby adjusting the flow rate of refrigerant flowing from the discharge chamber to the crank chamber. To do.

  The body 105 has an inner diameter of the lower half thereof expanded in a plurality of stages, and a disk-like stopper 123 is press-fitted near the center of the lower half in the axial direction. A stepped cylindrical valve seat forming member 120 is caulked and joined to the center of the stopper 123. A cylindrical actuating rod 119 is inserted into the valve seat forming member 120 so as to be slidable in the axial direction. The valve seat forming member 120 is disposed so as to contact the upper surface of the stopper 123, and a flange portion extending outward in the radial direction is provided at an upper end portion thereof. A valve seat 20 (sub valve seat) is formed by the lower surface of the flange portion. A stepped cylindrical valve body forming member 122 is disposed so as to surround the flange portion from the outside.

  The upper end portion of the valve body forming member 122 is slidably supported by the lower end portion of the valve forming member 115, and a flange portion extending inward in the radial direction is provided at the lower end portion. A valve body 21 (sub valve body) is formed by the flange portion. The valve body 21 is attached to and detached from the valve seat 20 from below to open and close the auxiliary valve (second valve portion), and adjust the flow rate of the refrigerant that is relieved from the crank chamber to the suction chamber. The connecting member 106 has a bottomed stepped cylindrical shape, and is press-fitted so that the lower end of the body 105 is inserted into the expanded upper half, and the solenoid 103 is connected to the bottom. An internal space surrounded by the body 105, the connection member 106, and the solenoid 103 forms a pressure chamber 28 into which the suction pressure Ps is introduced. In the pressure chamber 28, a power element 104 that detects the suction pressure Ps and operates in the axial direction is disposed.

  On the other hand, the solenoid 103 includes a bottomed cylindrical case 130 that also functions as a yoke, a bottomed cylindrical sleeve 131 that is fixed to the case 130, and an opening side of the sleeve 131 that is fixed to the case 130. A cylindrical core 32 inserted into the upper half, a columnar plunger 133 accommodated in the lower half on the bottom side of the sleeve 131 and arranged to face the core 32 in the axial direction, and from the outside The electromagnetic coil 34 that generates a magnetic circuit by the supplied current and the end member 135 provided to seal the lower end opening of the case 130 are provided. The bottom of the connection member 106 and the bottom of the case 130 are abutted with each other, and an insertion hole 29 is formed so as to penetrate the center of the bottom. The upper end portion of the core 32 is inserted into the insertion hole 29 and crimped outward, thereby connecting and fixing the connecting member 106 and the case 130 so as to be sandwiched from the inside.

  A long columnar shaft 136 is inserted through the center of the core 32 in the axial direction. The lower end portion of the shaft 136 is press-fitted coaxially with the upper end portion of the plunger 133. A refrigerant passage communicating with the pressure chamber 28 is formed in the gap between the core 32 and the shaft 136. A groove portion 137 is formed at a predetermined location on the outer peripheral surface of the plunger 133 along the axial direction. The refrigerant having the suction pressure Ps that has passed through the gap between the core 32 and the shaft 136 is further introduced into the lower portion of the plunger 133, that is, the back pressure chamber 39 through a passage formed between the groove 137 and the sleeve 131. . The shaft 136 has an upper end connected to the power element 104, and transmits a solenoid force to the operating rod 119 via the power element 104.

  The sleeve 131 is made of a non-magnetic material, and a central portion of the bottom thereof is slightly convex upward so that the plunger 133 can be supported from below. Further, a cylindrical bobbin 41 is extrapolated to the sleeve 131, and an electromagnetic coil 34 is wound around the bobbin 41. A stepped cylindrical heat transfer member 134 made of a resin material is interposed between the case 130 and the coil assembly in which the electromagnetic coil 34 is wound around the bobbin 41. The heat transfer member 134 transfers the heat generated by the electromagnetic coil 34 to the case 130 and increases its heat dissipation efficiency. A seal ring 47 is interposed in a space surrounded by the outer peripheral surface of the upper end portion of the core 32, the upper end surface of the sleeve 131, and the inner surface of the bottom portion of the case 130, thereby securing a seal inside and outside the solenoid 103.

  The lower end portion of the case 130 is enlarged in diameter to form an enlarged diameter portion 40 protruding outward in the radial direction, and a disk-like collar 142 is disposed on the inside thereof. The collar 142 is fixed to the case 130 by crimping the lower end portion of the enlarged diameter portion 40 inward. The collar 142 is made of a magnetic material and constitutes a magnetic circuit together with the case 130. An insertion hole 43 is provided at the center of the bottom of the collar 142, and the lower end of the sleeve 131 is exposed through the insertion hole 43. A pair of connection terminals 44 connected to the electromagnetic coil 34 extend from the bobbin 41 and extend through the collar 142 and the end member 135 to the outside. For convenience of explanation, only one of the pair is displayed in the figure.

  The end member 135 is attached so as to seal the entire structure in the solenoid 103 included in the case 130 from below. The end portion of the connection terminal 44 is drawn out from the end member 135 and is connected to an external power source (not shown). In addition, as a resin material which forms the edge part member 135, what has moderate hardness and elasticity, such as 66 nylon containing glass, for example is preferable. In order to ensure a certain level of mounting accuracy, it is preferable that the hardness is higher than that of rubber.

  A relatively small O-ring 48 is interposed between the upper end outer peripheral surface of the end member 135 and the lower end inner peripheral surface of the case 130. Further, an O-ring 49 is attached above the enlarged diameter portion of the case 130 so as to be externally inserted into the case 130. The O-ring 49 is larger than the O-ring 48 and is interposed between the attachment hole and the case 130 when the control valve 101 is attached to the attachment hole provided in the compressor housing (not shown). And restricts the entry of foreign matter from the outside into the housing.

7 is a partially enlarged cross-sectional view corresponding to the upper half of FIG.
A groove-like fitting portion 159 whose width gradually increases toward the inside of the body 105 is formed at a position including the port 11 on the outer peripheral portion of the body 105, and an annular filter is formed in the fitting portion 159. 12 is fitted. That is, the fitting part 159 includes a narrow part 160 and a large part 162 having a width larger than that of the narrow part 160. In the present embodiment, the fitting portion 159 is formed by cutting with a lathe. Specifically, first, a groove portion having the same width as the small width portion 160 and the same depth as the large portion 162 is formed so as to abut the bit having a T-shaped tip shape at a position including the port 11 of the body 105. Then, after the groove is formed, the cutting tool is moved as it is by shifting it by a predetermined amount above and below the body 105. Thereafter, the bite is returned to the original position in the vertical direction and then retracted to form a stepped groove as shown.

  After the fitting portion 159 is formed in this way, the filter 12 is inserted and fitted. The filter 12 is formed in an annular shape by rounding a long band-shaped metal mesh in the longitudinal direction so that both ends thereof overlap each other by a predetermined amount, and spot welding is performed on the overlap portion. Since the filter 12 has a width larger than the width of the large portion 162 as shown in the figure, the filter 12 is assembled to the fitting portion 159 in a fitted state with its upper and lower ends bent. For this reason, the filter 12 is reliably prevented from falling off.

  The valve forming member 115 has a bottomed cylindrical shape, and a communication hole 140 that communicates the inside and the outside is provided at the bottom. A space surrounded by the lower end portion of the valve forming member 115, the valve body forming member 122, and the valve seat forming member 120 communicates with the port 13 through the communication hole 140, and the pressure chamber 150 is filled with the crank pressure Pc. Form. A concave groove is provided around the lower portion of the valve forming member 115, and a spring 75 that biases the valve forming member 115 in the valve opening direction of the main valve is interposed between the concave groove and the body 105. . The operating rod 119 penetrates the valve seat forming member 120 in the axial direction, and one end side thereof extends to the pressure chamber 150 and is connected to the valve forming member 115, and the other end side extends to the pressure chamber 28 and is connected to the power element 104. Has been.

  Although omitted in the present embodiment, in a modification, a seal member is provided between the body 105 and the valve forming member 115 to restrict leakage of the discharged refrigerant introduced from the port 11 to the pressure chamber 28. You may do it. For example, a thin film sheet (ring-shaped) packing may be provided at the opening end of the insertion hole 24 on the port 11 side. You may comprise so that the inner peripheral part may be crimped | bonded to the sliding surface of the valve | bulb formation member 115 by a self-sealing effect | action when the differential pressure | fever acts on the packing.

  The power element 104 forms a hollow housing 181 interposed between the operating rod 119 and the shaft 136 and supported so as to be displaceable in the valve opening / closing direction, and a reference pressure chamber S sealed in the housing 181. And a reaction force transmission member 169 connected to the upper end of the pressure-sensitive member 182. The housing 181 is formed by joining a cylindrical bottomed first housing 184 and a second housing 185 obtained by press-molding a stainless steel plate so that their openings are abutted with each other. An accommodation space for the 182 and the reaction force transmission member 169 is formed.

  The first housing 184 is provided with a fitting convex portion 186 projecting upward at the center of the bottom thereof, and is connected to the shaft 136 so that the fitting convex portion 186 accommodates the upper end portion of the shaft 136. The first housing 184 has a corrugated side surface in the circumferential direction, and is slidably supported by the connecting member 106 at the outer apex of the corrugated shape. The lower end of the second housing 185 is joined (welded) to the upper end of the first housing 184. The second housing 185 supports the operating rod 119 from below at the bottom center. A plurality of insertion holes 90 for exposing a part of the reaction force transmission member 169 are provided on the outer periphery of the upper end of the second housing 185.

  The pressure-sensitive member 182 includes a pair of diaphragms 191 and 192 that face vertically (the opening and closing direction of the valve portion), a guide member 188 sandwiched between the pair of diaphragms, and a pair of stoppers joined to the pair of diaphragms. The members 193 and 194 and a spring 195 interposed between the pair of stopper members are included. The diaphragms 191 and 192 are both thin film disk-like metal diaphragms, and are mounted so as to seal the upper end opening and the lower end opening of the cylindrical guide member 188, respectively. That is, outer periphery welding is performed so that the outer peripheral edge of the diaphragm 191 is sandwiched between the guide member 188 and the ring member 96, and the outer peripheral edge of the diaphragm 192 is sandwiched between the guide member 188 and the ring member 97. Thus, the sealed reference pressure chamber S is formed by performing the outer periphery welding. Since this welding is performed in a vacuum atmosphere, the reference pressure chamber S is in a vacuum state, but the reference pressure chamber S may be filled with air or the like.

  The stopper member 193 has a stepped columnar shape, and its upper surface is joined to the center of the lower surface of the diaphragm 191. A flange portion 145 extending outward in the radial direction is provided at the upper end portion of the stopper member 193. On the other hand, the stopper member 194 also has a stepped columnar shape, and its lower surface is joined to the center of the upper surface of the diaphragm 192. A flange portion 146 extending outward in the radial direction is provided at the lower end portion of the stopper member 194. The spring 195 is interposed between the flange portion 145 and the flange portion 146, and urges the stopper member 193 and the stopper member 194 in a direction in which they are separated from each other. For this reason, the pressure-sensitive member 182 expands or contracts in the axial direction (the opening / closing direction of the valve portion) according to the differential pressure between the suction pressure Ps of the pressure chamber 28 and the reference pressure of the reference pressure chamber S. However, even if the differential pressure increases, if the pressure-sensitive member 182 contracts by a predetermined amount, the distal end surfaces of the stopper member 193 and the stopper member 194 come into contact with each other and are locked, so that the contraction is restricted.

  The spring 195 is a compression coil spring whose contact height when adjacent coils are in close contact is smaller than the total thickness of each coil. That is, the spring 195 is formed to have a barrel shape in which the outer diameter of the adjacent coil gradually changes, and the outer diameter of the central portion is larger than the end portion in the axial direction. It is supported as a support shaft, and the other end is assembled so as to be supported using the stopper member 194 as a support shaft. Thus, by adopting a barrel-shaped compression coil spring, the spring 195 can be formed more compactly than the magnitude of the load.

  The reaction force transmission member 169 has a disk shape, and has three leg portions 70 extending upward from the outer peripheral edge portion thereof through the housing 181 (only one is shown in the figure). The center position of the reaction force transmission member 169 is formed in a concave shape so as to be joined to the center of the upper end of the pressure sensitive member 182. That is, the concave portion and the stopper member 193 are fixed so that the central portion of the diaphragm 191 is sandwiched. A spring 79 is interposed between the reaction force transmission member 169 and the second housing 185 to urge them in the direction of separating them.

  An insertion hole 128 is provided at a position facing the leg portion 70 of the stopper 123, and the upper end portion of the leg portion 70 passes through the insertion hole 128 and extends into the upper space. The valve seat forming member 120 is configured to be press-fitted into the three legs 70 extending in this manner and to operate integrally with the legs 70. Accordingly, when the valve body 21 is seated on the valve seat 20 and the auxiliary valve is closed as shown in the drawing, the leg portion 70 is not displaced upward.

  In such a configuration, when the suction pressure Ps in the pressure chamber 28 becomes lower than the predetermined set pressure Pset during steady control of the control valve 101, the pressure-sensitive member 182 is deformed in the extending direction. At this time, since the auxiliary valve is in the closed state, the reaction force transmission member 169 restricts the upward displacement of the pressure sensitive member 182, and therefore the pressure sensitive member 182 is relatively displaced downward. That is, the reaction force from the valve seat forming member 120 acting on the reaction force transmission member 169 is transmitted to the shaft 136 via the pressure-sensitive member 182 and the housing 181, and a force in a direction to reduce the solenoid force by the solenoid 103 acts. To do. This set pressure Pset is basically adjusted in advance by the spring load of the spring 195, and is set as a pressure value that can prevent freezing of the evaporator from the relationship between the temperature in the evaporator and the suction pressure Ps. The set pressure Pset can be changed by changing the supply current (set current) to the solenoid 103.

  In the present embodiment, the effective pressure receiving diameter A of the main valve (the inner diameter of the opening end of the valve hole 16), the inner diameter B of the insertion hole 24, and the sliding portion of the valve element forming member 122 of the operating rod 119 The outer diameter C and the effective pressure receiving diameter D of the auxiliary valve (the outer diameter of the valve seat 20) are formed to be substantially equal. Therefore, the force due to the discharge pressure Pd acting on the operating rod 119 and the force due to the crank pressure Pc are cancelled. Further, the force due to the suction pressure Ps acting on the valve body forming member 122 is also canceled. For this reason, in the control state of the compressor, the valve element 18 opens and closes based on the solenoid force in the valve closing direction by the solenoid 103, the force in the valve opening direction by the spring 75, and the reaction force in the valve opening direction by the power element 104. Will work. On the other hand, the load of the spring 195 is set to be considerably larger than the load of the spring 79. For this reason, the closed state of the auxiliary valve can be maintained in the steady control state of the control valve 101.

Next, the operation of the control valve will be described.
8 and 9 are diagrams showing the operation of the control valve, and correspond to FIG. FIG. 7 already described shows the maximum capacity operation state of the control valve. FIG. 8 shows a state when the bleed function of the control valve is operated. FIG. 9 shows a relatively stable control state. The following description is based on FIG. 6 and with reference to FIGS. 7 to 9 as appropriate.

  In the control valve 101, when the solenoid 103 is not energized, that is, when the automotive air conditioner is not operating, no suction force acts between the core 32 and the plunger 133. Further, since the spring 75 urges the shaft 136 downward via the operating rod 119 and the power element 104, the valve body 18 is separated from the valve seat 17 and the main valve is fully opened. At this time, the refrigerant having the discharge pressure Pd introduced from the discharge chamber of the compressor into the port 11 passes through the fully opened main valve and flows from the port 13 to the crank chamber. Therefore, the crank pressure Pc is increased and the compressor is operated at the minimum capacity.

  In this case, since the suction pressure Ps is relatively high, the pressure-sensitive member 182 is contracted. At this time, since the solenoid force does not act, the power element 104 is displaced to the bottom dead center. As a result, the valve body 21 is separated from the valve seat 20 and the sub-valve is opened. Further, since the valve body forming member 122 is separated from the valve seat forming member 120, the power element 104 is interposed between the operating rod 119 and the shaft 136, but does not substantially function. On the other hand, when the valve forming member 115 is fully opened, the valve forming member 115 is displaced to the bottom dead center and comes into contact with the valve seat forming member 120, and the lower end portion of the operating rod 119 is sealed. That is, the second sub-valve is closed by the lower end surface of the actuating rod 119 and the upper end surface of the valve seat forming member 120, thereby restricting the derivation of the refrigerant from the crank chamber via the port 13, The minimum capacity operating state is maintained.

  On the other hand, when the maximum control current is supplied to the electromagnetic coil 34 of the solenoid 103, such as when the automobile air conditioner is started, the plunger 133 is attracted to the core 32 with the maximum suction force. At this time, as shown in FIG. 8, the solenoid force is directly transmitted to the operating rod 119 via the power element 104, the valve body 18 is seated on the valve seat 17, and the main valve is closed. At this time, since the operating rod 119 rises from the bottom dead center, the above-described second auxiliary valve is opened. On the other hand, since the suction pressure Ps is high and the pressure-sensitive member 182 is in the contracted state immediately after the start of the compressor at the time of high load such as in summer, the open state of the auxiliary valve in which the valve body 21 is separated from the valve seat 20 is maintained. .

  In the present embodiment, as the suction pressure Ps that allows the pressure-sensitive member 182 to be in a contracted state in this way, a value that can be opened at a predetermined high load such as in summer when the air conditioner is frequently used is set. The set value in the present embodiment is a load calculated by the effective pressure receiving area of the diaphragm 191 and the diaphragm 192 and the suction pressure Ps (more precisely, the differential pressure between the suction pressure Ps and the reference pressure in the reference pressure chamber S). The load in the contraction direction of the pressure-sensitive member 182 to which the load of the spring 79 is applied is the suction pressure Ps that can overcome the load in the extension direction of the pressure-sensitive member 182 by the spring 195.

  That is, by supplying a starting current to the solenoid 103, the main valve is closed to restrict the introduction of refrigerant discharged into the crank chamber, while the auxiliary valve is opened, so that the refrigerant in the crank chamber can be quickly transferred to the suction chamber. Relieve. In the present embodiment, the crank chamber is depressurized through a depressurization passage (an orifice or the like connecting the crank chamber and the suction chamber) formed in the compressor. In this way, the subvalve is opened quickly. Thus, the pressure reduction responsiveness can be maximized, and the compressor can be started quickly. When the suction pressure Ps decreases from this state, as shown in FIG. 7, the maximum capacity operation state in which both the main valve and the subvalve are closed is entered.

  Here, when the current value supplied to the solenoid 103 is in a control state set to a predetermined value, the suction pressure Ps is also somewhat low, so that the valve body 21 is placed in the valve seat 20 as shown in FIG. With the sub-valve closed, the valve element 18 operates to open and close the main valve. At this time, the valve body 18 balances the force in the valve opening direction by the spring 75, the solenoid force in the valve closing direction by the solenoid 103, and the force in the direction to reduce the solenoid force by the power element 104 operated by the suction pressure Ps. Stop at the valve lift position.

  For example, when the refrigeration load increases and the suction pressure Ps becomes higher than the set pressure Pset, the pressure-sensitive member 182 contracts, so that the power element 104 and thus the valve element 18 are displaced relatively upward (in the valve closing direction). As a result, the valve opening of the main valve decreases, and the compressor operates to increase the discharge capacity. As a result, the suction pressure Ps changes in a decreasing direction. Conversely, when the refrigeration load decreases and the suction pressure Ps becomes lower than the set pressure Pset, the pressure-sensitive member 182 extends. As a result, the reaction force of the reaction force transmission member 169 acts on the shaft 136 in a direction to reduce the solenoid force. As a result, the force in the valve closing direction on the valve body 18 is reduced, the valve opening of the main valve is increased, and the compressor operates to reduce the discharge capacity. As a result, the suction pressure Ps is maintained at the set pressure Pset, and excessive cooling is prevented.

  As described above, in the control valve 101 of the present embodiment, in the control valve 101 of the present embodiment, the groove-shaped fitting portion is located at the position including the port 11 into which the high-pressure discharged refrigerant is introduced. Is formed, and the filter 12 is fitted into the fitting portion. With such a configuration, a case for accommodating the filter becomes unnecessary. Further, since the filter is directly attached to the body 5, the filter structure can be realized simply and at low cost.

  The operating rod 119 and the shaft 136 are rigidly connected via the housing 181 without using an elastic member or the like, and the solenoid force is transmitted as it is to the valve body 18 of the main valve. For this reason, when the solenoid 103 is switched from OFF to ON and a starting current is supplied, the main valve can be quickly closed. In addition, the intake valve Ps at the time of starting the compressor is high particularly during high loads such as in summer, so that the auxiliary valve can be kept open. That is, since the sub valve can be opened at the same time as the main valve is closed, the introduction of the refrigerant into the crank chamber can be restricted and the refrigerant can be discharged from the crank chamber at the same time, and the compressor can be started quickly. . Further, since the actuating rod 119 is directly driven by the solenoid 103, even if foreign matter that has passed through the port 11 enters the gap between the body 105 and the valve forming member 115, the actuating rod 119 is driven when the control valve 101 is driven. Can be scraped out of the gap. For this reason, even if it does not arrange | position a sealing member in the opening part by the side of the port 11 of the insertion hole 24, generation | occurrence | production of the biting of a foreign material can be prevented or suppressed.

  The preferred embodiments of the present invention have been described above, but the present invention is not limited to the specific embodiments, and various modifications can be made within the scope of the technical idea of the present invention. Needless to say.

  In the above embodiment, an example in which a simple filter structure is applied to a so-called Ps sensing valve that performs compressor capacity control has been described. However, the control method and control target of the control valve to be applied are limited to these. Absent. For example, a so-called Pc sensing valve that senses the crank pressure Pc and controls it to keep it constant, or a so-called Pd− that keeps the differential pressure (Pd−Ps) between the discharge pressure Pd and the suction pressure Ps at a set differential pressure. You may apply to Ps valve. Further, the present invention may be applied to an electromagnetic valve that controls the working fluid in another device mounted on the vehicle such as a fuel injection valve instead of the vehicle air conditioner. Or you may apply to the solenoid valve which controls a working fluid in apparatuses other than a vehicle like the control valve which controls the pouring of a hot water supply apparatus, for example. Furthermore, the present invention may be applied not to an electromagnetic valve but to a mechanical control valve that opens and closes due to a differential pressure across the working fluid.

  DESCRIPTION OF SYMBOLS 1 Control valve, 2 Valve body, 3 Solenoid, 4 Power element, 5 Body, 16 Valve hole, 17 Valve seat, 18 Valve body, 19 Actuating rod, 20 Valve seat, 21 Valve body, 28 Pressure chamber, 36 Shaft, 69 Reaction force transmission member, 70 leg portion, 82 pressure sensitive member, 91, 92 diaphragm, 93, 94 stopper member, 95 spring, 101 control valve, 102 valve body, 103 solenoid, 104 power element, 105 body, 119 actuating rod, 136 shaft, 169 reaction force transmission member, 181 housing, 182 pressure sensitive member, 188 guide member, 191, 192 diaphragm, 193, 194 stopper member, 195 spring.

Claims (4)

A body formed with an introduction port through which a working fluid is introduced, a derivation port through which the working fluid is led out, and a fluid passage connecting the introduction port and the derivation port; a valve portion provided in the fluid passage; In a control valve provided with a filter that is disposed at the introduction port and restricts the inflow of foreign matter into the body,
A groove-like fitting portion provided at a position including the introduction port on the outer peripheral portion of the body;
A locking portion that is provided so as to cover at least both ends in the width direction of the fitting portion from the outside, and forms an opening at a position where the introduction port is included, and
With
The filter is made of an annular member having a width larger than the opening of the locking portion, and is fitted to the body so as to be fitted into the fitting portion and locked to the locking portion from the outside. A control valve characterized by being provided.   2. The control valve according to claim 1, wherein the filter is formed by rounding a long band-shaped metal mesh so that both ends in the longitudinal direction overlap each other by a predetermined amount. The body is configured such that a press-molded cylindrical second body is externally fitted to a cylindrical first body obtained by press molding,
The control valve according to claim 1, wherein the fitting portion is formed by the first body, and the locking portion is formed by the second body.   A groove portion whose width gradually increases toward the inside of the body is provided at a position of the outer peripheral portion of the body including the introduction port, and the fitting portion is formed by a portion having a large width of the groove portion. The control valve according to claim 1, wherein the locking portion is formed by a portion having a small width of the groove portion.

Images