JP2023062383A - Connector device and foot pump - Google Patents

Abstract

SOLUTION: A foot pump 12 comprises a connector device 10. In the connector device 10, an arm part 88 collides with a contact part 114 when a projection part 90 is inserted into a fitting hole 110 and the arm part 88 returns to its original shape. When relatively moving a first connector 44 and a second connector 46 to connect the first connector 44 and the second connector 46, after a seal member 98 is in airtight contact with an outer peripheral surface of a connection pipe part 48 to establish a seal, the projection part 90 is inserted into the fitting hole 110 and the arm part 88 collides with the contact part 114.SELECTED DRAWING: Figure 4

Description

The present invention relates to connector devices and foot pumps.

For example, Patent Literature 1 discloses a connector device including a first connector and a second connector that can be connected to each other. An air tube is connected to the first connector. The first connector has a tubular air supply/exhaust terminal. A rubber seal is attached to the outer surface of the supply/exhaust terminal. The second connector has an air supply/exhaust port into which the air supply/exhaust terminal is inserted.

Japanese Patent No. 5558130

In the conventional technology described above, since the rubber seal is attached to the outer surface of the supply/exhaust terminal, the rubber seal is exposed to the outside when the first connector is removed from the second connector. In this case, the user may touch the rubber seal while removing the first connector from the second connector. A rubber seal can be displaced from its reference position by being touched by a user. If the first connector and the second connector are connected to each other with the rubber seal deviated from the reference position, air (fluid) may leak from between the first connector and the second connector. Moreover, it is desirable that such a connector device has a configuration that allows the user to easily know that the connection between the first connector and the second connector has been completed.

An object of the present invention is to solve the problems described above.

One aspect of the present invention is a connector device comprising a first connector and a second connector that are connectable to each other, the first connector having a connecting tube portion through which fluid flows, and the second connector comprising: a connection hole into which the connection pipe portion is inserted; and an annular seal member disposed on an inner surface surrounding the connection hole, wherein one of the first connector and the second connector is connected to the connection pipe. an elastically deformable arm portion extending along the insertion direction of the portion into the connection hole; and a projecting portion projecting from the arm portion; a contact portion that contacts the protrusion to elastically deform the arm; and a fitting hole into which the protrusion is inserted, wherein the protrusion is inserted into the fitting hole and the arm When the arm portion returns to its original shape, the arm portion collides with the contact portion, and when the first connector and the second connector are relatively moved to connect the first connector and the second connector, the seal member is in air-tight or liquid-tight contact with the outer peripheral surface of the connection tube to establish a seal, the protrusion is inserted into the fitting hole, and the arm collides with the contact portion. .

Another aspect of the present invention is a sleeve that is attachable to and detachable from a leg of a human body, a pump device for supplying compressed air to an airbag of the sleeve, and the compressed air between the pump device and the airbag. and a connection tube for circulation, wherein the pump device and the connection tube are connected to each other by the connector device described above.

According to the present invention, since the annular seal member is arranged on the inner surface surrounding the connection hole of the second connector, the user can easily touch the seal member when the first connector is detached from the second connector. Can not. As a result, it is possible to suppress the seal member from deviating from the reference position. Therefore, the sealing member can effectively suppress leakage of fluid from between the first connector and the second connector. Further, when connecting the first connector and the second connector, the arm portion collides with the contact portion after the seal is established. Thereby, the user can easily know that the connection between the first connector and the second connector has been completed.

FIG. 1 is a schematic configuration diagram of a foot pump according to one embodiment of the present invention. 2 is a perspective view of the connector device of FIG. 1; FIG. 3 is a cross-sectional view of the connector device of FIG. 2; FIG. 4 is a partial cross-sectional perspective view of the first connector and the second connector of FIG. 2; FIG. FIG. 5 is a vertical cross-sectional view taken along line VV of FIG. 6 is an exploded perspective view of the second connector of FIG. 2; FIG. FIG. 7 is a first explanatory diagram of the fitting operation of the first connector and the second connector. FIG. 8 is a second explanatory diagram of the fitting operation of the first connector and the second connector. FIG. 9 is a third explanatory diagram of the fitting operation of the first connector and the second connector. FIG. 10 is a graph showing the relationship between the stroke and fitting resistance when the first connector and the second connector are fitted to each other.

As shown in FIG. 1, a foot pump 12 according to one embodiment of the present invention is a medical device that intermittently presses a leg of a human body to assist the return of venous blood in the leg. Foot pump 12 is used, for example, to perform intermittent pneumatic compressions to prevent thrombosis.

Foot pump 12 includes a plurality of sleeves 14 , a pumping device 16 and a plurality of connecting members 18 . Specifically, the foot pump 12 comprises two sleeves 14 , one pumping device 16 and two connecting members 18 . However, the number of sleeves 14, pump devices 16 and connecting members 18 can be set as appropriate.

The sleeve 14 is attachable to and detachable from the leg of the human body. Each sleeve 14 has a sleeve sheet 20 , a plurality of airbags 22 , a plurality of locking portions 24 , a plurality of sleeve tubes 26 and one sleeve connector 28 .

The sleeve sheet 20 has such a size and shape that it can be wrapped around the leg (lower leg or foot) of the human body. The sleeve sheet 20 is made of cloth, for example. However, an appropriate material can be adopted as the constituent material of the sleeve sheet 20 .

A plurality of airbags 22 are attached to the sleeve sheet 20 . Each airbag 22 is made of a material that can be inflated and deflated. Specifically, the airbag 22 is inflated by supplying compressed air supplied from the pump device 16 to the inside of the airbag 22 . The airbag 22 contracts when the compressed air held inside the airbag 22 is exhausted. In this embodiment, each sleeve 14 has four airbags 22 . However, each sleeve 14 may have one or more (other than four) airbags 22 .

A plurality of locking portions 24 are attached to the sleeve sheet 20 . The locking portion 24 holds the sleeve sheet 20 wrapped around the leg of the human body. The locking portion 24 is, for example, a hook-and-loop fastener. However, the locking portion 24 is not limited to the hook-and-loop fastener, and may be a hook, a button, or the like. In this embodiment each sleeve 14 has two stops 24 . However, each sleeve 14 may have one or more (other than two) locking portions 24 .

Compressed air flows through each sleeve tube 26 . One ends of the plurality of sleeve tubes 26 are connected to the plurality of airbags 22, respectively. The other ends of the plurality of sleeve tubes 26 are connected to sleeve connectors 28 . In this embodiment, each sleeve 14 has four sleeve tubes 26 (the same number as the airbags 22). However, each sleeve 14 may have one or more (other than four) sleeve tubes 26 .

The pump device 16 intermittently supplies compressed air to the inside of the plurality of airbags 22 of each sleeve 14 . A pumping device 16 evacuates compressed air from within the plurality of airbags 22 of each sleeve 14 . Pump device 16 has a case 30 and a plurality of pump connectors 32 . The case 30 covers a pump body (not shown) and the like. A plurality of pump connectors 32 are attached to the case 30 . In this embodiment, pump device 16 has two pump connectors 32 . However, the pump device 16 may have one or more (other than two) pump connectors 32 .

A plurality of connecting members 18 connect the plurality of sleeves 14 to the pumping device 16 . Each connecting member 18 has a plurality of connecting tubes 34 , a first connecting connector 36 and a second connecting connector 38 . One ends of the plurality of connection tubes 34 are connected to the first connection connector 36 . The other ends of the multiple connection tubes 34 are connected to a second connector 38 . In this embodiment, each connecting member 18 has four connecting tubes 34 (the same number as the airbags 22 of each sleeve 14). However, each connecting member 18 may have one or more (other than four) connecting tubes 34 . A first connector 36 is connectable to the pump connector 32 . A second connector 38 is connectable to the sleeve connector 28 .

Foot pump 12 includes a plurality of first connector devices 40 and a plurality of second connector devices 42 . The first connector device 40 connects the plurality of connecting tubes 34 and the pump device 16 to each other. First connector device 40 includes first mating connector 36 and pump connector 32 . The second connector device 42 connects the plurality of sleeve tubes 26 and the plurality of connecting tubes 34 to each other. The second connector device 42 includes the sleeve connector 28 and the second mating connector 38 .

The sleeve connector 28 and the first connector 36 are configured identically to each other. The pump connector 32 and the second connector 38 are configured identically to each other. Therefore, the first connector device 40 and the second connector device 42 are configured identically to each other. In the following description, the sleeve connector 28 and the first connection connector 36 may be called "first connector 44". Also, the pump connector 32 and the second connection connector 38 may be referred to as a "second connector 46". Further, the first connector device 40 and the second connector device 42 are sometimes referred to as the "connector device 10".

As shown in FIGS. 2-5, the connector device 10 includes a first connector 44 and a second connector 46. As shown in FIG. The first connector 44 is a male connector. The second connector 46 is a female connector. The first connector 44 and the second connector 46 are connectable to each other.

3 and 4, the first connector 44 includes a plurality of connecting tube portions 48 and a first connector main body 50. As shown in FIG. In this embodiment, the first connector 44 has four connecting tube portions 48 . However, the connection pipe portion 48 can be appropriately set according to the number of airbags 22 of each sleeve 14 .

The plurality of connecting pipe portions 48 are arranged in a row in the arrow X direction. The connecting pipe portion 48 extends in the arrow Y direction. Compressed air (fluid) flows through the connecting pipe portion 48 . The connecting pipe portion 48 extends in a circular tubular shape. The connecting tube portion 48 is integrally formed of polyacetate (POM), for example. However, the constituent material of the connecting pipe portion 48 can be set as appropriate.

The plurality of connection pipe portions 48 are inserted into a plurality of connection holes 132 of the second connector 46, which will be described later. Hereinafter, the direction in which the connecting pipe portion 48 is inserted into the connection hole 132 may be referred to as the first direction (direction of arrow Y1), and the direction opposite to the first direction may be referred to as the second direction (direction of arrow Y2). In addition, in each connecting tube portion 48, the end in the first direction may be referred to as the tip.

As shown in FIG. 5 , the outer peripheral surface of the end portion of the connection pipe portion 48 in the first direction has a tapered surface 52 whose diameter is reduced toward the tip of the connection pipe portion 48 . Tapered surface 52 includes a first tapered portion 56 and a second tapered portion 58 . The first taper portion 56 is tapered at a first taper angle α in the first direction. The end of the first tapered portion 56 in the first direction is positioned at the tip of the connecting pipe portion 48 . The second taper portion 58 is tapered at a second taper angle β in the first direction. The end of the second tapered portion 58 in the first direction continues to the end of the first tapered portion 56 in the second direction.

The first taper angle α is greater than the second taper angle β. The first taper angle α is preferably set to 10° or more and 20° or less. The second taper angle β is preferably set to 0.5° or more and 1.0° or less.

When the connector device 10 is the first connector device 40 , the connection tube 34 is connected to the end of each connection tube portion 48 in the second direction. When the connector device 10 is the second connector device 42 , the sleeve tube 26 is connected to the second direction end of each connecting tube portion 48 .

3-5, the first connector body 50 supports a plurality of connecting tube portions 48. As shown in FIG. The first connector main body 50 is integrally molded from a hard resin material. The first connector body 50 has a first cover portion 60, a holding portion 62, two pressing operation portions 64, and two claw portions 66 (see FIGS. 4 and 5).

The first cover portion 60 covers the plurality of connection pipe portions 48 from the outside. The first cover portion 60 includes a cover body 68 and a cover extension portion 70 . The cover main body 68 is configured in an annular shape. The cover main body 68 extends in the direction in which the plurality of connection pipe portions 48 are arranged (the arrow X direction).

The cover extending portion 70 is configured in an annular shape. The cover extending portion 70 extends in the first direction from the end face of the cover main body 68 in the first direction. The cover extending portion 70 extends in the direction in which the plurality of connecting pipe portions 48 are arranged. The extending end of the cover extending portion 70 is located in the second direction relative to the end of each connecting pipe portion 48 in the first direction. In other words, each connecting pipe portion 48 protrudes in the first direction from the extending end of the cover extending portion 70 . The cover extension 70 is thinner than the cover body 68 . The outer surface of the cover extending portion 70 is located inside the outer surface of the cover main body 68 . In other words, a step 72 (see FIGS. 3 and 4) is formed between the outer surface of the cover main body 68 and the outer surface of the cover extension portion 70 .

In FIG. 4 , each of two wall portions 74 extending in the direction of arrow X of the cover body 68 has a first notch portion 76 . The first notch 76 is located in the central portion of the cover body 68 in the extending direction (arrow X direction). Each of the two wall portions 78 of the cover extension portion 70 extending in the direction of the arrow X has a second notch portion 80 . The second notch 80 is located in the central portion of the cover extending portion 70 in the extending direction (arrow X direction). The second notch 80 communicates with the first notch 76 .

As shown in FIGS. 3 to 5, the holding portion 62 is connected to the inner surface of the cover body 68. As shown in FIGS. The holding portion 62 has a plurality of holding holes 82 . The connecting pipe portion 48 is inserted into the holding hole 82 . The holding portion 62 holds intermediate portions in the longitudinal direction of the plurality of connecting pipe portions 48 .

4 and 5, the two pressing operation portions 64 are located in the two first notches 76, respectively. Each pressing operation portion 64 includes a root portion 84 and an operation portion main body 86 . The root portion 84 extends in the first direction from the end of the cover body 68 in the second direction. The root portion 84 is elastically deformable in the thickness direction of the root portion 84 (the arrow Z direction orthogonal to the arrow X direction and the arrow Y direction). The operating portion main body 86 is connected to the extended end of the root portion 84 . The operation portion main body 86 is plate-shaped. A first notch portion 76 is present between the operation portion main body 86 and the cover main body 68 . The operating portion main body 86 is out of contact with each of the cover main body 68 , the cover extension portion 70 and the holding portion 62 . The length of the root portion 84 in the direction of the arrow X is shorter than the length of the operation portion main body 86 in the direction of the arrow X.

Each pawl portion 66 includes an arm portion 88 and a projection portion 90 . The arm portion 88 is connected to the inner surface of the operation portion main body 86 (the surface facing the holding portion 62). The arm portion 88 protrudes from the operation portion main body 86 in the first direction. The arm portion 88 is located in the second notch portion 80 . A second notch 80 is present between the arm 88 and the cover extension 70 . The arm portion 88 is out of contact with each of the cover main body 68 , the cover extension portion 70 and the holding portion 62 . The arm portion 88 is elastically deformable in the arrow Z direction.

The protruding portion 90 protrudes outward (in a direction away from the plurality of connecting pipe portions 48) from the protruding end portion of the arm portion 88. As shown in FIG. The protrusion 90 has a triangular shape when viewed from the arrow X direction. Projection 90 includes an inclined surface 92 and a stopper surface 94 . The inclined surface 92 is inclined in the second direction from the end surface of the arm portion 88 in the first direction toward the projecting end of the projecting portion 90 . The stopper surface 94 is connected to the inclined surface 92 and faces the second direction.

As shown in FIGS. 3-6, the second connector 46 includes a second connector body 96, a plurality of seal members 98, and a seal retaining member 100. As shown in FIGS. The second connector main body 96 is integrally molded from a hard resin material. The second connector body 96 includes a second cover portion 102 , a support wall portion 104 and a plurality of tube portions 106 .

4 and 6, the second cover portion 102 is annular. The second cover portion 102 extends in the arrow X direction. The second cover part 102 has a rectangular shape when viewed from the Z direction. Each of the two wall portions 108 extending in the direction of arrow X of the second cover portion 102 has one fitting hole 110 and a plurality of fixing holes 112 .

The fitting hole 110 extends in the arrow X direction. The fitting hole 110 has a rectangular shape when viewed from the arrow Z direction. Each fitting hole 110 is positioned in the central portion in the extending direction (the arrow X direction) of the second cover portion 102 . Each fitting hole 110 is a through hole penetrating through the second cover portion 102 .

As shown in FIGS. 4 and 5, each protrusion 90 of the first connector 44 is inserted into each fitting hole 110 . The end portion of the second cover portion 102 in the second direction (arrow Y2 direction) has a contact portion 114 that contacts the projection portion 90 and elastically deforms the arm portion 88 . The contact portion 114 guides the protrusion 90 to the fitting hole 110 . The contact portion 114 is a surface inclined outward toward the second direction. The fixing hole 112 is a through hole for fixing the seal holding member 100 to the second connector body 96 (see FIGS. 4 and 6).

In FIGS. 3-5, the support wall portion 104 is located inside the second cover portion 102 . The support wall portion 104 has a support body 116 and a plurality of tubular portions 118 . The support body 116 extends like a plate in a direction orthogonal to the arrow Y direction. The support body 116 is connected to the inner surface of the second cover portion 102 .

The cylindrical portion 118 protrudes from the support body 116 in the second direction. The plurality of cylindrical portions 118 are arranged in a row in the direction of the arrow X at intervals. In FIG. 5, the inner surface of cylindrical portion 118 has a first annular recess 120 and a second annular recess 122 . A seal member 98 is mounted in the first annular recess 120 . The second annular recess 122 is positioned in the arrow Y2 direction of the first annular recess 120 . The second annular recess 122 extends from the first annular recess 120 to the projecting end (the end in the second direction) of the tubular portion 118 . The diameter (hole diameter) of the second annular recess 122 is larger than the diameter (hole diameter) of each first annular recess 120 .

In FIG. 3, a plurality of pipe portions 106 protrude from the support wall portion 104 in the first direction (arrow Y1 direction). The inner holes of the plurality of tube portions 106 communicate with the inner holes of the plurality of cylinder portions 118 respectively. When the connector device 10 is the first connector device 40 , a plurality of air flow paths (not shown) inside the pump device 16 are connected to the plurality of pipe portions 106 . When the connector device 10 is the second connector device 42 , a plurality of connecting tubes 34 are connected to the plurality of tube portions 106 respectively.

In FIG. 6, the sealing member 98 extends annularly. The seal member 98 is in airtight sealing contact with the outer peripheral surface of the connection pipe portion 48 when the connection pipe portion 48 is inserted into the connection hole 132 (see FIG. 5). As a constituent material of the sealing member 98, fluororubber is preferable. In this case, the sliding resistance between the seal member 98 and the outer peripheral surface of the connecting pipe portion 48 can be effectively reduced. However, the constituent material of the seal member 98 may be nitrile rubber (NBR) or other rubber.

In FIG. 7, the outer diameter Da of the tip of the connecting pipe portion 48 is smaller than the inner diameter Db of the sealing member 98 in the initial state where the connecting pipe portion 48 is not in contact with the sealing member 98 . The maximum outer diameter Dc of the tapered surface 52 of the connecting pipe portion 48 (the outer diameter of the end of the second tapered portion 58 in the second direction) is larger than the inner diameter Db of the seal member 98 in the initial state.

As shown in FIG. 6 , the seal holding member 100 has a holding body 124 , a plurality of holding cylinders 126 and a plurality of fixing claws 128 . The holding body 124 extends in the direction of the arrow X in a plate shape. The plurality of holding cylinders 126 are arranged in a line in the direction of the arrow X at intervals. The holding tube portion 126 protrudes from the holding body 124 in the first direction (arrow Y1 direction). The fixed claw 128 extends from the holding body 124 in the first direction (arrow Y1 direction). The plurality of fixing claws 128 are fitted into the plurality of fixing holes 112 of the second cover portion 102, respectively. Thereby, the seal holding member 100 is fixed to the second cover portion 102 .

As shown in FIGS. 3 and 4, with the seal holding member 100 fixed to the second cover portion 102, the plurality of holding cylinder portions 126 are inserted into the plurality of second annular recesses 122, respectively. A protruding end face of the holding tube portion 126 is in contact with or close to the seal member 98 . That is, the holding tube portion 126 prevents the seal member 98 from slipping out in the second direction. With the seal holding member 100 fixed to the second cover portion 102, the cover extending portion 70 of the first connector 44 and the plurality of claw portions 66 are provided between the seal holding member 100 and the second cover portion 102. An insertion space 130 for insertion is formed (see FIGS. 3 to 5).

The second connector 46 has a plurality of connection holes 132 into which the plurality of connection tube portions 48 can be inserted. Connection hole 132 includes the inner hole of tubular portion 118 and the inner hole of holding tubular portion 126 . In this embodiment, the second connector 46 has four connection holes 132 (see FIG. 3). However, the number of connection holes 132 can be set as appropriate.

When connecting the first connector 44 and the second connector 46 to each other, the connecting tube portions 48 of the first connector 44 are inserted into the connecting holes 132 of the second connector 46, respectively, as shown in FIG. At this time, the cover extending portion 70 and the plurality of claw portions 66 are inserted into the insertion space 130 of the second connector 46 .

Then, as shown in FIG. 8, the inclined surface 92 of each claw portion 66 of the first connector 44 comes into contact with the contact portion 114 of the second connector 46 . As a result, the arm portion 88 is elastically deformed inward (toward the connection tube portion 48). Also, the tip of the connection tube portion 48 passes through the inner hole of the seal member 98 . After that, the seal member 98 comes into contact with the tapered surface 52 of the connection tube portion 48 .

At this time, the connection pipe portion 48 receives a reaction force (fitting resistance) from the seal member 98 . Specifically, as shown in FIG. 10, the fitting resistance when the seal member 98 contacts the connecting pipe portion 48 (when the stroke is La) is Ra. Here, the stroke is the relative distance between the first connector 44 and the second connector 46 in the direction in which the first connector 44 and the second connector 46 approach each other after the insertion of the connection tube portion 48 into the connection hole 132 is started. is the distance traveled.

Subsequently, when the first connector 44 and the second connector 46 are relatively moved in a direction in which the first connector 44 and the second connector 46 approach each other, the seal member 98 is moved radially by the tapered surface 52 of the connection tube portion 48 . pushed outwards. In other words, the seal member 98 is crushed between the tapered surface 52 of the connecting pipe portion 48 and the inner surface of the first annular recess 120 . Therefore, the mating resistance gradually increases.

As shown in FIG. 9, the seal member 98 airtightly contacts the outer peripheral surface of the connection pipe portion 48 to establish a seal when the seal member 98 gets over the first tapered portion 56 of the connection pipe portion 48 . At this point (when the stroke is Lb), the mating resistance becomes maximum (Rb) (see FIG. 10). In other words, mating resistance is greatest when the seal is established. The fitting resistance Rb when the seal is established is preferably 20N or less, more preferably 15N or less. However, the fitting resistance Rb may be greater than 20N. At this point, the protruding portion 90 of the claw portion 66 has not been inserted into the fitting hole 110 .

After that, when the first connector 44 and the second connector 46 are further moved relative to each other in the direction in which the first connector 44 and the second connector 46 approach each other, the fitting resistance gradually decreases as shown in FIG. The seal member 98 slides on the outer peripheral surface with little crushing after the seal is established. Therefore, it is believed that the mating resistance gradually decreases after the seal is established.

Then, when the stroke reaches Lc, the protruding portion 90 of the claw portion 66 is inserted into the fitting hole 110 (see FIG. 5). At this time, the elastically deformed arm portion 88 returns to its original shape. Therefore, the arm portion 88 collides with the contact portion 114 of the second cover portion 102 to generate a hammering sound. This completes the connection between the first connector 44 and the second connector 46 . When the protrusion 90 is inserted into the fitting hole 110, the seal member 98 is in airtight contact with the outer peripheral surface (second tapered portion 58) of the connecting pipe portion 48 to maintain the seal.

As shown in FIG. 10, in this embodiment, the fitting stroke length ΔL is set to 0.5 mm or more and 2.0 mm or less. The fitting stroke length ΔL is the length from when the sealing member 98 is in airtight contact with the outer peripheral surface of the connecting pipe portion 48 to establish a seal until the projecting portion 90 of the arm portion 88 is inserted into the fitting hole 110 . It is the relative movement distance between the first connector 44 and the second connector 46 . More preferably, the fitting stroke length ΔL is set to 0.5 mm or more and 1.0 mm or less.

This embodiment has the following effects.

According to this embodiment, since the ring-shaped sealing member 98 is arranged on the inner surface surrounding each connection hole 132 of the second connector 46 , the user can seal the first connector 44 after removing the first connector 44 from the second connector 46 . Member 98 is not easily accessible. As a result, it is possible to prevent the seal member 98 from deviating from the reference position. Therefore, the sealing member 98 can effectively prevent compressed air from leaking from between the first connector 44 and the second connector 46 . Also, when connecting the first connector 44 and the second connector 46, the arm portion 88 collides with the contact portion 114 after the seal is established. At this time, the user can hear the hammering sound generated when the arm portion 88 collides with the contact portion 114 . Alternatively, the user can feel the vibration generated when the arm portion 88 collides with the contact portion 114 . Thereby, the user can easily know that the connection between the first connector 44 and the second connector 46 has been completed.

Mating resistance is greatest when the seal is established. Further, the fitting resistance when the seal is established is 20N or less.

According to such a configuration, when connecting the first connector 44 and the second connector 46, it is possible to effectively prevent an excessive load from acting on the seal member 98. FIG.

By the way, in the connector device 10 , the greater the fitting resistance, the greater the insertion resistance of the projection 90 into the fitting hole 110 , so that the arm 88 is less likely to vigorously collide with the contact 114 . The fitting resistance is reduced because the seal member 98 slides on the outer peripheral surface of the connecting pipe portion 48 after the seal is established and before the protrusion 90 is inserted into the fitting hole 110 .

In this embodiment, the fitting stroke length ΔL is 0.5 mm or longer.

With such a configuration, it is possible to effectively reduce the fitting resistance when the protrusion 90 is inserted into the fitting hole 110 .

The outer peripheral surface of the connection pipe portion 48 includes a tapered surface 52 whose diameter is reduced toward the tip of the connection pipe portion 48 . The outer diameter Da of the tip of the connecting pipe portion 48 is smaller than the inner diameter Db of the sealing member 98 in the initial state where the connecting pipe portion 48 is not in contact with the sealing member 98 .

With such a configuration, the tip of each connecting pipe portion 48 can be easily passed through the inner hole of the seal member 98 .

The maximum outer diameter Dc of the tapered surface 52 is larger than the inner diameter Db of the seal member 98 in the initial state.

With such a configuration, the seal member 98 can be gradually expanded radially outward by the tapered surface 52 . As a result, it is possible to suppress a sudden increase in fitting resistance, so that the connection tube portion 48 can be smoothly inserted into the connection hole 132 .

Tapered surface 52 includes a first tapered portion 56 and a second tapered portion 58 . The first taper portion 56 is tapered at a first taper angle α in the first direction. The second taper portion 58 is tapered at a second taper angle β in the first direction. The end of the second tapered portion 58 in the first direction continues to the end of the first tapered portion 56 in the second direction. The first taper angle α is greater than the second taper angle β. The sealing member 98 is in contact with the second tapered portion 58 in a state where the connection between the first connector 44 and the second connector 46 is completed.

According to such a configuration, the length of the tapered surface 52 along the extending direction of the connection tube portion 48 can be suppressed while suppressing a sudden increase in fitting resistance.

The first connector 44 has a plurality of connection tube portions 48 . The second connector 46 has a plurality of connection holes 132 and seal members 98, respectively.

With such a configuration, the plurality of connection pipe portions 48 can be smoothly fitted into the plurality of connection holes 132 .

The seal member 98 is made of fluororubber. The connecting pipe portion 48 is made of polyacetate.

According to such a configuration, fitting resistance can be effectively suppressed.

Connector device 10 may be applied to medical devices other than foot pump 12 . In this case, a liquid may flow through the connecting tube portion 48 . When liquid flows through the connecting pipe portion 48 , the sealing member 98 is in liquid-tight sealing contact with the outer peripheral surface of the connecting pipe portion 48 . In the connector device 10 , the first connector 44 may have the fitting hole 110 , and the second connector 46 may have the pressing operation portion 64 and the claw portion 66 .

It should be noted that the present invention is not limited to the above-described embodiments, and can take various configurations without departing from the gist of the present invention.

The above-described embodiment is a connector device (10) comprising a first connector (44) and a second connector (46) connectable to each other, wherein the first connector is a connecting tube portion (48) through which fluid flows. The second connector has a connection hole (132) into which the connection tube portion is inserted, and an annular seal member (98) arranged on the inner surface surrounding the connection hole, Either one of the first connector and the second connector has an elastically deformable arm portion (88) extending along the direction of insertion of the connecting pipe portion into the connection hole, and a protrusion projecting from the arm portion. (90), and the other of the first connector and the second connector includes a contact portion (114) that contacts the protrusion to elastically deform the arm portion, and a contact portion (114) into which the protrusion is inserted. and a fitting hole (110), wherein when the protrusion is inserted into the fitting hole and the arm returns to its original shape, the arm collides with the contact portion and the first When connecting the first connector and the second connector by moving the connector and the second connector relative to each other, after the sealing member comes into airtight or liquid-tight contact with the outer peripheral surface of the connecting tube portion to establish a seal. , a connector device in which the protrusion is inserted into the fitting hole and the arm collides with the contact portion.

In the connector device described above, mating resistance when connecting the first connector and the second connector may be maximized when the seal is established.

In the above connector device, the mating resistance when the seal is established may be 20N or less.

In the connector device described above, the fitting stroke length (ΔL), which is the relative movement distance between the first connector and the second connector from the establishment of the seal until the arm portion collides with the contact portion, is , 0.5 mm or more.

In the connector device described above, the outer peripheral surface of the connecting pipe portion includes a tapered surface (52) that decreases in diameter toward the tip of the connecting pipe portion, and the outer diameter (Da) of the tip end of the connecting pipe portion is It may be smaller than the inner diameter (Db) of the seal member in an initial state in which the connecting pipe portion is not in contact with the seal member.

In the connector device described above, the maximum outer diameter (Dc) of the tapered surface may be larger than the inner diameter of the seal member in the initial state.

In the connector device described above, when the insertion direction is defined as a first direction and the direction opposite to the insertion direction is defined as a second direction, the tapered surface extends toward the first direction at a first taper angle (α). and a second tapered portion (58) tapered at a second taper angle (β) in the first direction, wherein the second tapered portion of the The end in the first direction is connected to the end in the second direction of the first taper portion, the first taper angle is larger than the second taper angle, and the connection between the first connector and the second connector is provided. is completed, the sealing member may abut against the second tapered portion.

In the connector device described above, the first connector may have a plurality of connection pipe portions, and the second connector may have a plurality of connection holes and seal members.

In the connector device described above, the sealing member may be made of fluororubber, and the connection tube portion may be made of polyacetate.

The above embodiment includes a sleeve (14) that can be attached to and removed from the leg of a human body, a pump device (16) for supplying compressed air to an airbag (22) of the sleeve, and a combination of the pump device and the airbag. a connecting tube (34) for circulating said compressed air therebetween, said pumping device and said connecting tube being connected to each other by a connector device as described above; Discloses the pump.

In the above foot pump, the sleeve has a sleeve tube (26) for circulating the compressed air between the airbag and the connection tube, and the connection tube and the sleeve tube are connected by the connector device. may be connected to each other.

DESCRIPTION OF SYMBOLS 10... Connector apparatus 12... Foot pump 14... Sleeve 16... Pump apparatus 22... Air bag 26... Sleeve tube 34... Connection tube 44... First connector 46... Second connector 48... Connection tube part 52... Tapered surface 56... First first connector Taper portion 58 Second taper portion 88 Arm portion 90 Projection portion 98 Seal member 110 Fitting hole 114 Contact portion 132 Connection hole α First taper angle β Second taper angle

Claims (11)

A connector device comprising a first connector and a second connector connectable to each other,
The first connector has a connecting tube portion through which a fluid flows,
The second connector is
a connection hole into which the connection pipe portion is inserted;
an annular seal member disposed on an inner surface surrounding the connection hole,
Either one of the first connector and the second connector is
an elastically deformable arm portion extending along the insertion direction of the connection pipe portion into the connection hole;
a projecting portion projecting from the arm portion,
the other of the first connector and the second connector,
a contact portion that contacts the protrusion and elastically deforms the arm;
and a fitting hole into which the protrusion is inserted,
When the protrusion is inserted into the fitting hole and the arm returns to its original shape, the arm collides with the contact portion,
When the first connector and the second connector are relatively moved to connect the first connector and the second connector, the sealing member comes into airtight or liquid-tight contact with the outer peripheral surface of the connection tube portion, and the sealing is performed. A connector device, wherein, after being established, the protrusion is inserted into the fitting hole and the arm collides with the contact portion. 2. The connector device of claim 1, comprising:
A connector device, wherein mating resistance when connecting said first connector and said second connector is maximized when said seal is established. 3. The connector device of claim 2, wherein
The connector device, wherein the mating resistance when the seal is established is 20N or less. 4. The connector device according to claim 2 or 3,
A fitting stroke length, which is a relative movement distance between the first connector and the second connector from when the seal is established until the arm portion collides with the contact portion, is 0.5 mm or more. Device. The connector device according to any one of claims 1 to 4,
the outer peripheral surface of the connecting pipe portion includes a tapered surface that decreases in diameter toward the tip of the connecting pipe portion;
The connector device according to claim 1, wherein an outer diameter of the distal end of the connection pipe portion is smaller than an inner diameter of the seal member in an initial state in which the connection pipe portion is not in contact with the seal member. A connector device according to claim 5, wherein
The connector device, wherein the maximum outer diameter of the tapered surface is larger than the inner diameter of the seal member in the initial state. A connector device according to claim 6, wherein
When the insertion direction is defined as a first direction and the direction opposite to the insertion direction is defined as a second direction,
The tapered surface is
a first tapered portion whose diameter is reduced at a first taper angle in the first direction;
a second tapered portion whose diameter is reduced at a second taper angle in the first direction,
the end of the second tapered portion in the first direction is connected to the end of the first tapered portion in the second direction;
The first taper angle is greater than the second taper angle,
The connector device according to claim 1, wherein the sealing member is in contact with the second tapered portion when the connection between the first connector and the second connector is completed. The connector device according to any one of claims 1 to 7,
The first connector has a plurality of connection tube portions,
The connector device, wherein the second connector has a plurality of the connection holes and the seal members. The connector device according to any one of claims 1 to 8,
The sealing member is made of fluororubber,
The connector device, wherein the connecting tube portion is made of polyacetate. A sleeve that can be attached and detached to the leg of the human body,
a pumping device for supplying compressed air to the airbag of the sleeve;
A foot pump comprising a connection tube for circulating the compressed air between the pump device and the airbag,
A foot pump, wherein the pump device and the connection tube are connected to each other by the connector device according to any one of claims 1 to 9. A foot pump according to claim 10,
The sleeve has a sleeve tube for circulating the compressed air between the airbag and the connection tube,
The foot pump, wherein the connection tube and the sleeve tube are connected to each other by the connector device.

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