RU2069284C1 - Pressure differential control valve with diaphragm drive - Google Patents

Abstract

FIELD: radiator type heating systems; maintenance of constant pressure differential and uniform delivery. SUBSTANCE: valve has body, first diaphragm capsule and second diaphragm capsule. Two different design versions of pressure differential valve can be made using similar components connected in different manner. Fasteners of first diaphragm capsule or fasteners of first diaphragm capsule and second diaphragm capsule are made in form of sliding bushings. Support surface made on first diaphragm engages with rod of sealing member or with one end of second diaphragm shaft provided with limiting ring on other end. Limiting ring engages with rod of sealing member. Second diaphragm is installed on shaft for longitudinal displacement. EFFECT: enlarged operating capabilities. 7 cl, 4 dwg

Description

 The invention relates to the field of valve engineering and, in particular, is intended for use in heating systems having radiators, in which the pressure difference between the inlet line and the return line must be kept constant for uniform flow.

 A known differential pressure control valve with a membrane actuator, which contains a housing with inlet and outlet nipples and a saddle and a sealing element located between them with a stem hermetically installed in the neck part of the body, is attached to the fasteners of the neck part by means of fasteners, the capsule of the first membrane or connected with each other using fasteners of the capsule of the first membrane and the second membrane with a roller, and the upper block with the regulating Ruzyne and the connecting axis associated with the first membrane. The membrane capsules are made of two half shells.

 The known pressure differential valve may optionally be equipped with one capsule of the first membrane or capsules of the first and second membranes to double the active membrane surface by using a membrane of the same size. The operation of the capsules of the first and second membranes is the same / 1 /.

 A disadvantage of the known valve is that the second membrane serves to double the action of the first membrane and does not affect the control of the differential pressure.

 The objective of the invention is the creation of such a control valve of the differential pressure, which could alternately affect the control of the differential pressure and the introduction of an additional control element.

 This technical result is achieved in that the upper block is attached to the capsule of the first membrane. The fasteners of the throat portion of the housing or the fasteners of the specified throat portion of the body of the second membrane are made in the form of inserts, which are fixed, for example, crimped, and the fasteners of the capsule of the first membrane or the fasteners of the specified capsule of the first membrane and the fasteners of the capsule of the second membrane installed sleeves, while on the first membrane a supporting surface is formed in contact with the stem of the sealing element or with one end of the roller a membrane equipped with a restrictive ring at the other end cooperating with the stem of the sealing element, and the second membrane is mounted on the roller with the possibility of longitudinal movement.

 During the differential pressure control, the second membrane moves along the rod. However, if the flow limit is exceeded, this second membrane acts on the valve.

 This is possible due to the fact that the capsule of the second membrane is located between the capsule of the first membrane and the valve body, both membranes have non-rigid connections, therefore they independently affect the valve axis.

 The non-rigid connection makes it possible for the individual component to be easily joined together without any special means that must be provided between the valve stem, the contact surface and the membrane stem.

 The non-rigid connection also allows the free movement of the second membrane during the differential pressure control operation and allows this membrane to have an effect if the limit value of the flow rate is exceeded.

 The use of external threads on the inserts and the execution of the sleeves in the form of connecting nuts results in a very simple and durable connection of the individual components.

 A guide hole made in the capsule insert of the second membrane holds the stem of the membrane on its axial path of movement in such a way that, despite the non-rigid connection, it serves as a reliable transmitting force element.

 It is advisable in the insertion of the capsule of the second membrane to make a through channel communicating the submembrane cavity of the capsule of the first membrane with the supmembrane cavity of the capsule of the second membrane.

 It is necessary to connect the submembrane cavity of the capsule of the second membrane with the inlet nipple using a connecting channel made in the sealing element and its rod, and an outlet made in the insert of the neck part of the housing.

 It is also advisable to fix the connecting rings fixed to the connecting nuts to one half-shell of two capsules.

 It is also necessary to place a throttling element in the valve body, which forms a limiter, the pressure drop on which is used to actuate the capsules of the second membrane.

The invention is illustrated in the drawing,
where on:
FIG. 1 shows a longitudinal section of a first embodiment of a pressure differential valve with one membrane capsule,
FIG. 2 shows a longitudinal section of the second variant of the differential pressure valve with two membrane capsules,
FIG. 3 shows an enlarged longitudinal section of the capsules of the first and second membranes,
FIG. 4 is a schematic block diagram of a second embodiment of a differential pressure valve.

 The differential pressure valve comprises an upper block 1, a capsule of a first membrane 2, a capsule of a second membrane 3, and a valve body. For the second embodiment (Fig. 2), all four components are used; for the first embodiment (Fig. 1), the capsule of the second membrane is not used.

 The upper unit 1 has a rotating head 5, with which the support plate 6 can be adjusted for the set position spring 7. This set position spring 7 acts by means of the intermediate element 8 with upward force on the connecting roller 9 belonging to the capsule of the first membrane 2. More Moreover, the upper block 1 has a base 10, with which it can be attached to the capsule of the first membrane 2.

 The valve body 4 has an inlet nipple 11, an outlet nipple and a valve seat 13 between them. In the neck portion 14 there is an insert 15 that forms a guide means for the valve stem 16, which also contains a sealing element 17. The restrictor is formed by a throttling element 19, which is presented in the form of a cap with an inwardly rounded flange and is vertically adjustable externally by means of a screw 20 to change the cross section of the stopper. The valve chamber 21 between the stopper 18 and the valve seat 13 is in a state of connection by means of a connecting channel 22, which passes through the sealing element 17 and the valve stem 16, and by means of an outlet 23 passing through the insert 15, with the upper side of this insert 15. Installation cup 24 of sheet metal separates this connecting channel from the outlet side of the valve chamber. The valve stem 16 supports at its upper end a plate 26 on which the valve spring 27 rests, which loads the sealing element 17 in the opening direction. On the outside of the neck portion 14 is a locking element 28 in the form of an external thread.

 The capsule of the first membrane 2 contains two half-shells 30 and 31, which are joined together at their edge by a crimp connection 32, which also holds the edge of the membrane 33 fully clamped. The upper half-shell 30 contains a connecting fitting 34 for the control line and an insertion 35 installed through compression, through which the working a roller 9 sealed to the outside. At the opposite end, the connecting ring is crimped and by means of the step 37 holds the fastening element 38 in the form of a connecting nut. The membrane 33 is reinforced by a double plate 39, in the center of which the insert 40 is mounted by crimping. The roller 9 is connected to the insert by the joint 41. This insert contains a check valve 42, which allows the pressure space 43 below the membrane 33 to connect to the pressure space 44 above of this membrane when the pressure difference is too large. On the lower side of the insert 40 there is a supporting surface 45. The membrane 33 is loaded with a first spring 46, which is located in the pressure space 43, and in the opposite direction is loaded with a spring 47, which is placed in the pressure space 44. The spring 46 protrudes through the open portion 48 of the lower half shell 31 and abuts against the capsule of the second membrane 3. Spring 47 abuts against the bore 49 of insert 35.

 The capsule of the second membrane 3 also contains two half-shells 50 and 51, which are joined together at their edges by a crimp connection 52, which also compresses the edge of the membrane 53. The upper half-shell contains a connecting fitting 54 for the control line. The insert 55 is mounted by compression and has on its outer side a fastening element 56 in the form of an external thread. The insert 55 forms a guide means 57 for the rod 58 of the membrane and has a through channel 59. The lower half-shell 51 contains a compression ring 60 connected to it by compression, which, by means of the step 61, carries a fastening element 62 in the form of a connecting nut. An open portion 63 remains inside this connecting ring. The membrane 53 is strengthened by a double plate 64. On the one hand, the double plate comes into contact with the locking element 65 of the diaphragm rod 58, however, in the other direction, the membrane is biased on this rod. The membrane 53 divides the capsule of the second membrane 3 into two pressurized spaces 66 and 67 and is loaded with a loading spring 68, which passes through the open portion 63, and abuts against the plane 69 of the valve body 4.

 The fasteners are designed so that both the fastener 38 of the capsule of the first membrane 2 and the fastener 62 of the capsule of the second membrane 3 can interact with the fastener 28 on the valve body 4. Additionally, the capsule of the second membrane 3 has a fastener 56, which has the ability to act together with the fastener 38 of the capsule of the first membrane 2.

 The differential pressure valve is located in the return line of the heating system, in the first embodiment shown in FIG. 1, the capsule of the first membrane 2 is mounted by means of fasteners 28 and 38 on the valve body 4, and the connection 34 is connected to the input line. This means that the overpressure space 44 serves as an inlet pressure carrier, and the overpressure space 43, since it is connected to the valve chamber 18 via the connecting line 22, is a backpressure (backpressure) carrier. Consequently, the capsule of the first membrane 2 forms a force acting in the direction of closing the valve, which essentially counteracts the force of the setpoint spring (position) in such a way that an equilibrium state develops. Under the influence of the valve spring 27, the plate 26 of the valve stem 16 lays firmly on the supporting surface 45 of the insert 40.

 In the second embodiment shown in FIG. 2, the capsule of the second membrane 3 is additionally inserted between the capsule of the first membrane 2 and the valve body 4. By means of fasteners 28 and 62 acting together, it is connected to the valve body 4, and by means of fasteners 56 and 38 acting together, it is connected to the capsule the first membrane 2. The length of the stem of the membrane 58 corresponds approximately to the height of the capsule of the second membrane 3 and its size is set so that, under the influence of the valve spring 27, the plate 26 of the valve stem 16 non-rigidly comes into contact with the stop element 65 of the membrane rod 16, and its end surface also non-rigidly came into contact with the abutment surface 45 of the insert 40. However, it seems possible for the pressure difference in the capsule of the second membrane 3 to control the valve if the pressure difference acting in it exceeds spring force 68. Then the stem of the membrane 58 rises from the supporting surface 45 and controls the sealing element 17, then translating it into the closed position.

 A preferred application example of the second embodiment is illustrated in FIG. 4. The heating system has several radiators 70, 71 and 72, each of which is supplied with hot water by means of thermostatic valves 73, 74 and 75. From the main discharge line 76 by means of a discharge discharge line 76 by means of a discharge discharge line 77. Hot water is returned by means of a discharge return line 78 and the main return line 79 to a central source of thermal energy. The pressure difference valve according to FIG. 2, is installed in the discharge return line 78. The connection 34 is connected to the discharge discharge line 77, and the connection 54 is connected to the discharge return line 78. The connection line 22 connects the lower pressure space 66 of the capsule of the second membrane 3 to the valve chamber 21. The through channel 59 connects the upper space of the increased pressure 67 capsules of the second membrane 3 with the lower space of the increased pressure 43 capsules of the first membrane 2. Therefore, the capsule of the first membrane 2 controls the valve so that repad pressure between the discharge branch line 77 and branch return line 78 remains approximately constant. The capsule of the second membrane 3 ensures that the valve will throttle whenever the pressure drop through the restrictor 18 becomes too large. Since the restrictor 18 located inside the valve body 4 is adjustable, the maximum required flow rate can be set using spring 68, designed for all cases.

Claims (7)

 1. The differential pressure control valve with a diaphragm actuator, comprising a housing with inlet and outlet nipples and a saddle and a sealing element located between them with a stem sealed in the neck of the housing, to the fastening elements of which, through independent fasteners, the capsule of the first membrane or connected between each other by means of fasteners of the capsule of the first membrane and the second membrane with a roller, and the upper block with the control spring installed in it and the connecting axis associated with the first membrane, the capsules made of two half shells, characterized in that the upper block is attached to the capsule of the first membrane, the fasteners of the neck part of the body or the fasteners of the specified neck part of the body and the capsule of the second membrane are made in the form of fixed for example, crimp connection, inserts, and fasteners of the capsule of the first membrane or fasteners of the specified capsule of the first membrane and fasteners of the capsule of the second membrane They are mounted in the form of movably mounted sleeves, while on the first membrane a supporting surface is contacted with the rod of the sealing element or with one end of the roller of the second membrane provided with a restrictive ring interacting with the rod of the sealing element at the other end, and the second membrane can be mounted on the roller longitudinal displacement.  2. The valve according to claim 1, characterized in that the inserts are made of an external thread, and the bushings are made in the form of connecting nuts.  3. The valve according to claims 1 and 2, characterized in that a guide hole is made in the capsule insert of the second membrane and a roller of the second membrane is installed in it.  4. The valve according to claim 3, characterized in that a through channel is made in the capsule insert of the second membrane, communicating the submembrane cavity of the capsule of the first membrane with the supmembrane cavity of the capsule of the second membrane.  5. The valve according to claims 1 to 4, characterized in that the submembrane cavity of the capsule of the second membrane is connected to the inlet nipple by means of a connecting channel made in the sealing element and its rod, and an outlet made in the insert of the neck part of the body.  6. The valve according to paragraphs. 2 5, characterized in that to one half-barrel of the two capsules are fixedly fixed connecting rings fixing the connecting nuts.  7. The valve according to claims 1 to 6, characterized in that an adjustable throttling element is installed in the housing opposite the stem sealing element.

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