KR102162928B1 - Coil-spring fixing structure and duplex reciprocating pump - Google Patents

Abstract

The retainer member 30 includes a first retainer 31 having a fitting portion 33 that fits inside an end of the coil spring 14, and a second retainer 32 that fits inside the first retainer 31. Consists of When the first retainer 31 and the second retainer 32 are fitted, the outer peripheral portion 34 of the tip end of the second retainer 32 contacts the inner side of the fitting portion 33, so that the plurality of jaws 37 are wedge-shaped. Extends outward by The retainer member 30 is fixed to the end of the coil spring 14 by pressing the inner side of the end portion of the coil spring 14 by a plurality of jaws 37 extending outward.

Description

Coil spring fixed structure and 2-station reciprocating pump {COIL-SPRING FIXING STRUCTURE AND DUPLEX RECIPROCATING PUMP}

The present invention relates to a coil spring fixing structure of a retainer member for attaching a coil spring to an end of a rod-shaped shaft and a two-station reciprocating pump.

Conventionally, a pair of closed spaces is divided into a pump chamber and an operation chamber by movable partition members such as bellows connected by a connecting shaft, and by alternately introducing a working fluid into the pair of operation chambers, the connecting shaft is reciprocated. A two-station reciprocating pump is known in which a pump chamber is alternately compressed and elongated.

In this type of two-station reciprocating pump, a pair of suction valves and discharge valves are switched from one pump chamber side to the other pump chamber side, respectively, at the end of the reciprocating movement stroke of the connecting shaft. A pulsating pulsation that causes harm occurs. As one that suppresses this pulsation and enables stable pump operation at all times, for example, a two-station reciprocating pump disclosed in Patent Document 1 is known.

According to this two-station reciprocating pump, based on the output of a displacement sensor that continuously detects the displacement of a pair of movable partition members, the overlapping distance in which the compression process of one pump chamber and the compression process of the other pump chamber partially overlap is determined. A pair of movable partition members are driven by switching the valve mechanism so as to have.

By the way, the connecting shaft in the conventional two-station reciprocating pump disclosed in Patent Document 1 is configured with a coil spring as an elastic member attached to the shaft. The connection between the coil spring and the shaft is not described in detail in Patent Document 1, but is usually performed by attaching a retainer member press-fitted to the end of the coil spring and attached to the end of the shaft.

International Publication No. 2010/143469

However, in the method of fixing the retainer member to the end of the coil spring by press fitting as described above, for example, when the size of the coil spring increases, the inner diameter tolerance increases, and as a result, the deviation of the manufactured inner diameter of the coil spring increases. It was difficult to provide an appropriate press-fitting value for the retainer member. For this reason, particularly for a coil spring having a large size, there is a problem that the retainer member cannot be reliably fixed to the end of the coil spring and attached to the shaft.

The present invention has been made in view of such a point, and an object of the present invention is to provide a coil spring fixing structure and a two-station reciprocating pump capable of reliably fixing a retainer member to its end portion and attaching it to a shaft even with a coil spring having a large size.

A coil spring fixing structure according to an embodiment of the present invention is a coil spring fixing structure of a retainer member for mounting a coil spring to an end of a rod-shaped shaft, wherein a retainer member for attaching the end of the coil spring to the end of the shaft is provided. And the retainer member comprises a first retainer having a fitting portion fitted inside an end portion of the coil spring, and a second retainer fitting inside the first retainer, and the first retainer The fitting portion of the second retainer has a plurality of jaws formed so as to extend outward by contacting the tip outer peripheral portion of the second retainer inside, and a wedge action by fitting the second retainer to the first retainer The plurality of jaws extending outwardly by pressing the inner side of the end of the coil spring, the retainer member is fixed to the end of the coil spring.

In another embodiment of the present invention, the first retainer includes the fitting portion formed in a cylindrical shape that is fitted inside the end of the coil spring, and the plurality of the fitting portion formed so as to extend from the tip side of the fitting portion toward the base end side. And an annular portion formed in the shape of a disk contacting the end of the coil spring with a larger diameter than the fitting portion, and an annular portion having a first threaded portion therein, and the second retainer The fitting portion and the fitting portion so that the second screw portion threaded to the first screw portion is formed on the outer periphery of the base end, and the outer peripheral portion of the tip contacts the inner side of the ship portion of the plurality of jaws in a wedge shape, and It is arranged coaxially with respect to the annular portion and is formed in a cylindrical shape.

A two-station reciprocating pump according to an embodiment of the present invention includes a case member forming a pair of spaces in an axial direction therein, and a case member disposed in the pair of spaces so as to be expandable and contracted in the axial direction, respectively. A pair of movable partition members dividing the space into a pump chamber and an operation chamber in the axial direction, respectively, a connection shaft for freely connecting the pair of movable partition members in an axial direction through a coil spring, and a suction side of the pump chamber are provided. A suction valve for guiding the transfer fluid to the pump chamber, a discharge valve provided on a discharge side of the pump chamber to discharge the transfer fluid from the pump chamber, and introducing a working fluid into the operation chamber, and receiving the working fluid from the operation chamber. A two-station reciprocating pump having a valve mechanism for discharging and transferring the transfer fluid by expanding and contracting the pair of movable partition members, wherein the connecting shaft comprises a pair of rod-shaped shafts and the pair of shafts. The coil spring is mounted, and a retainer member mounted on each of the end portions in the axial direction of the coil spring and mounted on the pair of shafts, and the retainer member has a fitting portion that fits inside the end of the coil spring. Consisting of a first retainer and a second retainer fitted to an inner side of the first retainer, the fitting portion includes a plurality of jaws formed so as to extend outward by contacting the tip outer peripheral portion of the second retainer inside, and the The plurality of jaws extending outwardly by a wedge action by fitting the second retainer to the first retainer is characterized in that the retainer member is fixed to the end of the coil spring by pressing the inside of the end of the coil spring. do.

In one embodiment of the present invention, another coil spring having a smaller diameter than the coil spring is disposed inside the coil spring and between the retainer members.

According to the present invention, even with a coil spring having a large size, the retainer member can be reliably fixed to the end thereof and mounted on the shaft.

1 is an exploded perspective view showing a retainer member applied to a coil spring fixing structure according to an embodiment of the present invention.
2 is a side view showing a part of the coil spring in cross section in order to explain a method of fixing a coil spring using the same retainer member.
3 is a side view showing a part in cross section to explain a method of fixing a coil spring using the same retainer member.
4 is an exploded perspective view showing a modified example of the same retainer member.
5 is a perspective view showing a retainer member applied to another coil spring fixing structure.
6 is a side view showing the same retainer member.
7 is a perspective view showing a retainer member applied to another coil spring fixing structure.
Fig. 8 is a side view showing the same retainer member.
9 is a diagram showing a configuration of a two-station reciprocating pump to which a coil spring fixing structure according to an embodiment of the present invention is applied.
10 is a partial cross-sectional view of a connecting shaft in the same pump.
11 is a partial cross-sectional view of another connecting shaft in the same pump.

Hereinafter, a coil spring fixing structure and a two-station reciprocating pump according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is an exploded perspective view showing a retainer member applied to a coil spring fixing structure according to an embodiment of the present invention. 2 and 3 are side views showing a part in cross section to explain a method of fixing a coil spring by a retainer member. The retainer member 30 applied to the coil spring fixing structure according to the present embodiment is made of a resin molded member such as polyphenylene sulfide (PPS).

The retainer members 30 are mounted on the ends of the coil springs 14, respectively. As shown in FIG. 1, the retainer member 30 includes a first retainer 31 mounted on an end of the coil spring 14 and a second retainer 32 fitting inside the first retainer 31. Done. The first retainer 31 includes a cylindrical fitting portion 33 that fits inside the end of the coil spring 14, and a disk-shaped annular portion that contacts the end of the coil spring 14 with a larger diameter than the fitting portion 33. It has (35). The fitting portion 33 and the annular portion 35 are integrally molded.

In the fitting portion 33 of the first retainer 31, a coarse root portion 37b is positioned toward the front end side of the fitting portion 33, and a shipbuilding portion is located toward the annular portion 35 side. A plurality of jaw portions 37 formed such that 37a) are positioned are provided at equal intervals along the circumferential direction of the fitting portion 33. These jaws 37, when the outer peripheral portion 34 of the tip of the second retainer 32 to be described later comes into contact with a tapered surface 37d provided inside the jaws 37, thereby contacting the rough root portion 37b. On the other hand, the shipbuilding part 37a side is formed to expand outward.

Around each jaw portion 37, for example, a U-shaped slit 37c is formed. This slit 37c communicates with a round hole 37e formed in the vicinity of the rough root portion 37b. The round hole 37e is provided in order to improve the mechanical strength of the rough part 37 by dispersing the concentration of the stress according to the rough part 37b when the rough part 37 is displaced. Further, a first threaded portion 35a is formed inside the annular portion 35.

The second retainer 32 is formed in a cylindrical shape in which a second threaded portion 32a that fits into the first threaded portion 35a of the first retainer 31 is formed outside. On the tip side of the second retainer 32, a tapered tip outer peripheral portion 34 is formed. The outer periphery of the tip portion 34 contacts the inner tapered surface 37d of the ship portion 37a of each jaw portion 37 in a wedge shape. This second retainer 32 is disposed coaxially with respect to the fitting portion 33 and the annular portion 35 of the first retainer 31.

The retainer member 30 configured in this way is attached to the coil spring 14 as shown in FIGS. 2 and 3. That is, as shown in Fig. 2, first, the first retainer 31 is placed in a coil spring so that the fitting portion 33 is pinched inside the end of the coil spring 14 and the annular portion 35 contacts this end. 14) Place the insert at the end.

Next, a second retainer 32 is inserted inside the first retainer 31, and a rotationally fastening jig is placed in a pair of grooves 32b facing the radial direction formed on the rear end surface of the second retainer 32. Insert the back and rotate the second retainer 32 little by little with the axial direction of the coil spring 14 as the center of rotation so that the second threaded part 32a engages with the first threaded part 35a, and the first retainer The second retainer 32 is put on the inside of (31).

When the second retainer 32 is threaded with respect to the first retainer 31, the outer peripheral portion 34 of the tip of the second retainer 32 becomes a tapered surface 37d of each jaw 37 of the first retainer 31. ) Against the wedge. Then, the outer peripheral portion 34 of the tip end of the second retainer 32 gradually expands each jaw portion 37 in the fitting portion 33 of the first retainer 31 so that the shipbuilding portion 37a extends outward.

Accordingly, as shown in FIG. 3, the outer circumferential surface of each jaw portion 37 formed in the fitting portion 33 of the first retainer 31 contacts the inside of the end portion of the coil spring 14, and The second retainer 32 is fitted to the first retainer 31 and the retainer member 30 is attached to the end of the coil spring 14 in a state as if the end is pressed from the inside. Finally, the coil springs 14 are attached by attaching the retainer members 30 respectively attached to the end portions of the coil springs 14 to a pair of shafts, for example, not shown in the shape of a rod.

In this way, if the coil spring 14 is mounted on the shaft by using the retainer member 30 having the structure as described above, for example, the size of the coil spring 14 is increased based on the inner diameter tolerance that increases depending on the case where the size of the coil spring 14 is made larger than the conventional one The resulting coil spring 14 sufficiently absorbs the deviation of the inner diameter, and the retainer member 30 is reliably mounted to its end in a state always centered with respect to the coil spring 14, and slidably mounted on the shaft. It becomes possible. In addition, either of the retainer members 30 may be fixedly attached to the shaft.

4 is an exploded perspective view showing a modified example of the retainer member. Other than the retainer member 30 described above, the basic configuration is the same, but a retainer member having the following structure may be used, for example. That is, as shown in Fig. 4(a), the retainer member 30A is formed of the first retainer 31 and the second retainer 32 in the same manner as the retainer member 30, but the first retainer 31 The difference is that the size in the circumferential direction of the plurality of jaws 37 formed in the fitting portion 33 of) is reduced, and the number is increased from 4 to 8. However, there is an advantage that the strength of the mold can be increased with four more than eight coarse portions 37.

In addition, as shown in Fig. 4(b), the retainer member 30B is in the vicinity of the rough root portion 37b of each jaw portion 37 at the fitting portion 33 of the first retainer 31 of the retainer member 30A. It is different from the retainer member 30A in that the round hole 37e of is omitted. Even if the retainer members 30A and 30B configured in this way are used, the same effects as those of the fixing structure in the case of using the retainer member 30 can be exhibited.

5 is a perspective view showing a retainer member applied to another coil spring fixing structure. Fig. 6 is a side view showing the retainer member. 7 is a perspective view showing a retainer member applied to another coil spring fixing structure. 8 is a side view showing the retainer member.

5 and 6, the retainer member 50 is made of a resin molded member similar to the retainer member 30 and the like. The retainer member 50 is integrally formed into a cylindrical fitting portion 51 that fits inside the end of the coil spring 14 and a disk shape larger in diameter than the fitting portion 51 by contacting the end of the coil spring 14 It has the annular part 52 which was made.

In addition, the retainer member 50 is formed on the outer circumferential surface of the fitting portion 51, a stopper 53 for preventing the fitting portion 51 from falling off from the end of the coil spring 14, and a fitting portion. 51 and the rotation preventing protrusion 54 as a displacement preventing portion that prevents displacement of the fitting position of the end portion of the coil spring 14 and the fitting portion 51, formed at a predetermined position of the stepped portion of the annular portion 52. Have.

The stopper 53 for preventing falling off of the retainer member 50 is formed to substantially round the outer circumferential surface of the fitting portion 51 along the winding direction of the coil spring 14. Further, the rotation preventing projection 54 of the retainer member 50 is formed so as to contact the spring end 14a in the winding direction at the end of the coil spring 14.

The retainer member 50 configured in this way is attached to the end of the coil spring 14 by inserting rotation with respect to the end of the coil spring 14 with the axial direction as a rotating shaft. Then, the retainer member 50 from the coil spring 14 after attaching the retainer member 50 to the end of the coil spring 14 by the above-described stopper 53 and rotation preventing protrusion 54 Off-axis and rotational movement of the retainer member 50 relative to the coil spring 14 are prevented.

7 and 8, the retainer member 60 is made of a resin molded member similarly to the retainer member 50 and has a fitting portion 61 and an annular portion 62. In addition, the retainer member 60 includes a wall-shaped stopper 63 formed along the circumferential direction on the outer peripheral surface of the front end side of the fitting portion 61, and a predetermined position of the stepped portion of the fitting portion 61 and the annular portion 62. It has a projection 64 for preventing rotation formed in.

Further, the stopper 63 for preventing the retainer member 60 from falling off is formed to protrude in a direction crossing the axial direction of the coil spring 14 and substantially accompany the outer peripheral surface of the fitting portion 61. In addition, the rotation preventing protrusion 64 of the retainer member 60 contacts the spring end 14a similarly to the rotation preventing protrusion 54.

And in a predetermined portion in the circumferential direction between the stopper 63 for preventing falling off of the fitting portion 61 and the protrusion 64 for preventing rotation, a stepped portion from the tip of the fitting portion 61 to the annular portion 62 is cut. A plurality of slits 65 in the opened state are formed. In the illustrated example, three slits 65 are formed, one in the vicinity of both ends of the stopper 63 for preventing falling off, and one in the vicinity of the protrusion 64 for preventing rotation, in total.

The retainer member 60 thus constructed is attached to the end of the coil spring 14 by pressing and inserting it along the axial direction. In addition, in order to prevent the stopper 63 for preventing dropping from contacting the coil spring 14 and making it difficult to insert when the retainer member 60 is inserted, the plurality of slits 65 are, in particular, a portion in which the stopper 63 for preventing dropping is formed. It is provided in order to make it easy to bend the fitting part 61 of the inside. Even with the retainer member 60 having such a structure, it is possible to prevent rotational movement or deviation from the axial direction from the coil spring 14.

9 is a diagram showing a configuration of a two-station reciprocating pump to which a coil spring fixing structure according to an embodiment of the present invention is applied. 10 is a partial cross-sectional view of a connecting shaft in a two-station reciprocating pump, and FIG. 11 is a partial cross-sectional view of another connecting shaft in the same pump. As shown in Fig. 9, the two-station reciprocating pump to which the coil spring fixing structure according to the present embodiment is applied is of a double acting type, and is configured as follows, for example.

As shown in Fig. 9, on both sides of the pump head 1 arranged in the central portion, a pair of cylinders 2a and 2b in the shape of a user cylinder as a case member are coaxially arranged, and a pair of these cylinders A pair of spaces are formed inside (2a, 2b). In these pair of spaces, a pair of bellows 3a and 3b in the shape of a user cylinder are coaxially arranged, respectively.

The opening ends of the bellows 3a and 3b are fixed to the pump head 1, and shaft fixing plates 4a and 4b are fixed to the bottom of the bellows 3a and 3b. The bellows (3a, 3b) is made of, for example, a fluorine resin, the inside as the pump chambers (5a, 5b), and the outside as the operation chambers (6a, 6b) to partition the inner space of the cylinders (2a, 2b). It constitutes a movable partition member.

The bellows 3a and 3b are provided with, for example, ridges 28a and valleys 28b alternately formed along the axial direction, and in the axial direction at predetermined intervals, for example 2 It is provided with an annular ring portion 29 that is formed integrally with each other. The number of ring portions 29 can be arbitrarily configured. The bellows 3a and 3b are of the same shape as the normal bellows without the ring part 29, have the same thickness, and the number of peaks 28a and valleys 28b that have the same operating resistance. The bellows 3a and 3b having such a structure are superior in temperature characteristics as compared to the bellows not having the ring portion 29, so that the pressure resistance performance can be improved without deteriorating the operating efficiency.

One end of the shafts 7a and 7b extending coaxially is fixed to the shaft fixing plates 4a and 4b. The other ends of the shafts 7a and 7b pass through the centers of the bottoms of the cylinders 2a and 2b, respectively, through the seal member 8 to the outside of the cylinders 2a and 2b. It is extended. At the other ends of the shafts 7a and 7b, connecting plates 9a and 9b are fixed by nuts 10. The connecting plates 9a and 9b are connected by connecting shafts 11a and 11b at the upper and lower positions in the drawings of the cylinders 2a and 2b.

Here, the connection shafts 11a and 11b will be described in detail. As shown in Fig. 10, each of the connecting shafts 11a and 11b includes rod-shaped shafts 12 and 13, a coil spring 14 mounted between the shafts 12 and 13, and the coil spring 14 Each of the retainer members 30 are mounted on the ends of the shafts in the axial direction of each of the shafts 12 and 13, respectively. In addition, although only the connection shaft 11 is shown in FIG. 10, the same configuration can be adopted for the connection shaft 11b.

In addition, each of the connecting shafts 11a and 11b is fitted and fixed to the concave portion 13a at the end of the shaft 13, for example, and in the space portion 12a formed inside the shaft 12, the shaft 12 It is provided with a rod-shaped slide shaft 39 disposed freely forward and backward in the axial direction through a bearing portion 38 mounted in the opening 12b of the end portion. The bearing portion 38 is made of a linear ball bearing, for example.

At the ends of the shafts 12 and 13 of each of the connecting shafts 11a and 11b, metal sleeves 40 having a convex cross-sectional shape made of a metal material such as stainless steel that are mounted and fixed by bolts 41 are disposed, respectively. Moreover, at least one bolt 41 of the shaft 12 fixes the bearing part 38 together with the metal sleeve 40.

The retainer member 30 is attached to the ends of the shafts 12 and 13 through this metal sleeve 40. The coil spring 14 is mounted to the shafts 12 and 13 freely sliding through the metal sleeve 40 after being centered by the retainer member 30. Further, each of the connecting shafts 11a and 11b is fixed to the connecting plates 9a and 9b by bolts 15.

The pump head 1 of the twin reciprocating pump is provided with an inlet 16 and a discharge port 17 for conveying fluid in a position facing the side of the pump. In addition, in the pump head 1, suction valves 18a, 18b are provided at positions from the suction ports 16 to the pump chambers 5a, 5b, and are discharged in the path from the pump chambers 5a, 5b to the discharge ports 17. Valves 19a and 19b are provided.

Proximity switches 21a and 21b are mounted on the outer wall surfaces of the bottoms of the cylinders 2a and 2b. The proximity switches 21a and 21b detect that the bottoms of the bellows 3a and 3b are most retracted, for example, that the inner surfaces of the connecting plates 9a and 9b are close. Further, displacement sensors 23a and 23b are attached to the fixed plates 22a and 22b extending from the cylinders 2a and 2b.

The displacement sensors 23a and 23b detect displacement with the outer surfaces of the connecting plates 9a and 9b, for example, a laser displacement meter, an MR (magnetic resistance element) sensor, a capacitive sensor, a linear encoder, a high frequency oscillation type. A proximity displacement sensor, an optical fiber type displacement sensor, or the like can be preferably used. The detection signals from these proximity switches 21a and 21b and the displacement sensors 23a and 23b are input to the controller 25 that controls the two-station reciprocating pump.

On the other hand, air (operating fluid) from an air source (operating fluid source) such as an air compressor (not shown) is supplied to the solenoid valves 27a and 27b after being limited to predetermined pressures by regulators 26a and 26b, respectively. . For this reason, since the pressure fluctuation in one operation chamber 6a, 6b does not affect the pressure in the other operation chamber 6b, 6a, it also has a pulsation reduction effect accordingly.

Further, the regulators 26a and 26b are not limited to two, but may be configured as one. In this case, a precision regulator can be used. Here, the solenoid valve 27a is now in the off state (exhaust state), the solenoid valve 27b is in the on state (air introduction state), and the pump chamber 5a is in the expansion process, and the pump chamber 5b is in the contraction process. do.

At this time, with the intake valve 18a and the discharge valve 19b open, the intake valve 18b and the discharge valve 19a are in a closed state, so that the liquid to be conveyed, which is the conveying fluid, is transferred from the inlet 16 It is introduced into the pump chamber 5a and is discharged from the pump chamber 5b through the discharge port 17. In addition, at this time, the output of the displacement sensor 23b falls according to the separation of the connecting plate 9a.

The controller 25 monitors the output of the displacement sensor 23b, and when the magnitude of the output of the displacement sensor 23b becomes, for example, less than a predetermined threshold value THR, the solenoid valve 27a is turned on to remove air. It is introduced into the operation chamber 6a. Accordingly, the pump chamber 5a is switched from the expansion process to the compression process.

However, at this point, since air is continuously supplied to the other operation chamber 6b, the pump chamber 5b also maintains the compression process. Accordingly, the suction valves 18a and 18b are in a closed state, the discharge valves 19a and 19b are in an open state, and the liquid is discharged from both pump chambers 5a and 5b. And the coil spring 14 of the connection shaft 11a, 11b is compressed in order to absorb the dimensional change between both ends of the bellows 3a, 3b at this time.

Further, when the proximity switch 21b detects the stroke end, the solenoid valve 27b is switched to air exhaust. And since the bellows 3b is pulled by the connecting shafts 11a and 11b to start elongation, the pump chamber 5b is converted to an expansion process. The liquid is transferred by repeating the above operation in the left and right pump chambers 5a and 5b. In the two-station reciprocating pump configured in this way, since the above-described coil spring fixing structure is applied, it is possible to smoothly follow the movement of the connecting shafts 11a and 11b even under a wide pulsating pressure.

And the connection shafts 11a and 11b may have the following configuration, for example. As shown in FIG. 11, each connecting shaft 11a, 11b is inside the coil spring 14 between the shafts 12 and 13 and between the retainer member 30, the auxiliary coil spring 70 and the auxiliary It has a double spring configuration with a retainer 71.

The auxiliary coil spring 70 is formed to have a smaller diameter than the coil spring 14 and is disposed between the coil spring 14 and the slide shaft 39. The auxiliary retainer 71 includes an insertion portion 72 inserted into an end portion of the auxiliary coil spring 70 and a disk portion 73 contacting the end portion of the auxiliary coil spring 70. The auxiliary retainers 71 are each attached to the end of the auxiliary coil spring 70 by, for example, press fitting. The rear side of the disk portion 73 of the auxiliary retainer 71 is supported by at least one of the front end surfaces of the metal sleeve 40 in a state in which contact separation is possible. When the connection shafts 11a and 11b of the double spring method are employed, it becomes possible to smoothly follow the movement of the connection shafts 11a and 11b even in a wider range of pulsating pressures.

1: pump head
2a, 2b: cylinder
3a, 3b: Belos
4a, 4b: fixing plate
5a, 5b: pump chamber
6a, 6b: operating room
7a, 7b: shaft
9a, 9b: connecting plate
11a, 11b: connecting shaft
12, 13: shaft
14: coil spring
14a: spring end
30, 50, 60: no retainer
31: first retainer
32: second retainer
32a: second threaded portion
33: fitting part
34: tip outer periphery
35: annular part
35a: first threaded portion
37: grandfather
37a: Ministry of Shipbuilding
37b: Cho Geunbu
37c: slit
37d: tapered surface
37e: round hole
38: bearing part
39: slide shaft
40: metal sleeve
70: auxiliary coil spring
71: auxiliary retainer
72: insert
73: disc

Claims (4)

As a coil spring fixing structure of a retainer member for mounting a coil spring to an end of a rod-shaped shaft,
A retainer member for mounting the end of the coil spring to the end of the shaft,
The retainer member includes a first retainer having a cylindrical fitting portion that fits inside the end of the coil spring, and a second retainer that fits inside the first retainer,
The fitting portion of the first retainer is formed so that a tip portion extends from a tip side of the fitting portion toward a base end side, and a plurality of jaw portions formed so as to extend outward by contacting the tip outer peripheral portion of the second retainer inside. Has (爪部),
By fitting the second retainer to the first retainer, the plurality of jaws extending outwardly by a wedge action press the inner side of the end of the coil spring, so that the retainer member is fixed to the end of the coil spring But,
The first retainer has an annular portion having a larger diameter than the fitting portion and formed in a disc shape contacting an end of the coil spring and having a first threaded portion therein,
In the second retainer, a second threaded portion threaded to the first screw portion is formed on an outer periphery of the base end, and the outer periphery of the tip contacts the inner side of the shipbuilding portion of the plurality of jaws in a wedge shape. The coil spring fixing structure, characterized in that it is disposed coaxially with respect to the fitting portion and the annular portion to be formed in a cylindrical shape. delete A case member forming a pair of spaces along the axial direction therein,
A pair of movable partition members disposed in the pair of spaces so as to be expandable and contractible in the axial direction, respectively, and partitioning the pair of spaces into a pump chamber and an operation chamber, respectively,
A connection shaft for freely connecting the pair of movable partition members in an axial direction through a coil spring,
A suction valve provided on the suction side of the pump chamber to guide a conveyed fluid to the pump chamber,
A discharge valve provided on the discharge side of the pump chamber to discharge the transfer fluid from the pump chamber;
A valve mechanism for introducing a working fluid into the operating chamber and discharging the working fluid from the operating chamber,
As a two-station reciprocating pump that transfers the transfer fluid by expanding and contracting the pair of movable partition members,
The connection shaft includes a pair of rod-shaped shafts, the coil spring mounted between the pair of shafts, and retainer members respectively mounted to end portions in the axial direction of the coil spring and mounted on the pair of shafts, ,
The retainer member includes a first retainer having a cylindrical fitting portion that fits inside the end of the coil spring, and a second retainer that fits inside the first retainer,
The fitting portion includes a plurality of jaws formed such that a tip portion extends from a front end side of the fitting portion toward a base end side, and extends outward by contacting the tip outer peripheral portion of the second retainer inside,
By fitting the second retainer to the first retainer, the plurality of jaws extending outwardly by a wedge action press the inner side of the end of the coil spring, so that the retainer member is fixed to the end of the coil spring But,
The first retainer has an annular portion having a larger diameter than the fitting portion and formed in a disc shape contacting an end of the coil spring and having a first threaded portion therein,
In the second retainer, a second threaded portion threaded to the first screw portion is formed on an outer periphery of the base end, and the outer periphery of the tip contacts the inner side of the shipbuilding portion of the plurality of jaws in a wedge shape. Two-station reciprocating pump, characterized in that it is disposed coaxially with respect to the fitting portion and the annular portion to be formed in a cylindrical shape. The method of claim 3,
A two-station reciprocating pump, characterized in that another coil spring having a smaller diameter than the coil spring is disposed inside the coil spring and between the retainer members.

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