JP6388271B1 - Glove wearing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a glove wearing device which does not require an exhaust mechanism using a motor.
When the front side of the lever 24a of the one-way notch mechanism 24 is pulled up, the tip of the lever 24a is detached from the slider recess 34. Then, the slider 30 is driven in a direction to be pushed out from the support frame 20 by the urging force of the tension springs 33 and 33. Since this movement enlarges the internal space of the bellows 25 in the support frame 20 and the internal space of the slider 30, negative pressure is generated inside. The glove placed on the open end of the slider 30 is pulled by the pressure of the outside air due to the negative pressure inside, and further inflates according to the negative pressure. When the negative pressure is generated, the bellows bottom opening hole 21 is closed and the negative pressure is maintained.
[Selection] Figure 2

Description

  The present invention relates to a glove wearing apparatus for wearing rubber gloves.

Gloves using elastic resin and rubber are routinely used in various fields. Gloves that are airtight regardless of the material are generally called rubber gloves.
Since rubber gloves with high adhesion take time to wear, attach the rubber glove opening to the cylindrical opening of the bottomed cylindrical case and supply negative pressure into the case. Therefore, a glove wearing device that generates a negative pressure around the rubber gloves and inflates the rubber gloves is used.

  In order to supply negative pressure into the case in this way, the glove wearing device shown in Patent Document 1 or Patent Document 2 needs to operate the exhaust device with a motor or generate negative pressure with human power.

International Publication No. 2008-038438 JP-A-53-63789 JP 2002-065696 A

Although the exhaust device is convenient, it requires a power source, so that it is limited in the place of installation, and even if a battery is installed, it requires time for replacement and charging. Further, the size and cost of the exhaust device itself are also problems.
In the one shown in Patent Document 3, it is necessary to insert the other hand into the container while performing an operation of pushing with one hand at the time of mounting operation, and it is troublesome to operate with both hands at the same time. You can't even wear it. While pushing with one hand, you have to push it with the other hand, so you inevitably push it down vertically. This is because the main body moves due to the pushing-in force in the oblique direction. That is, the installation direction is necessarily limited.
In addition, you must remove the worn gloves from the container.
The present invention provides a more convenient glove wearing device.

  The present invention has a bottomed cylindrical outer case and a glove opening portion which is slidable with respect to the inner peripheral surface of the outer case and is formed in a substantially cylindrical shape and protrudes from the outer case. An inner case, an urging mechanism for urging the inner case in a direction in which the inner case is pushed out in a slidable range in the outer case, and an airtight communication with the inner space of the inner case. Thus, when the inner case and the outer case are separated from each other, the volume of the inner space is increased, and when the inner case and the outer case are close to each other, the inner space is reduced. Thus, a notch mechanism that relatively holds and releases the inner case at the back side position of the outer case and a valve mechanism that maintains and releases the positive pressure and the negative pressure in the airtight case are provided.

In the above configuration, the inner case is slidable with respect to the inner peripheral surface of the outer case, and is formed in a substantially cylindrical shape so that an opening portion of the glove can be attached at a portion protruding from the outer case.
Since the urging mechanism can urge the inner case in a direction in which the inner case is pushed out within the slidable range in the outer case, the inner case is moved to the outer side while releasing the positive pressure in the airtight case by the valve mechanism. When moved to the far side within the slidable range in the case, the volume of the internal space of the airtight case is reduced, but the positive pressure in the airtight case is released. In this state, the inner case can be relatively held at the back side position of the outer case against the biasing mechanism by the notch mechanism. Next, the inside of the airtight case is cut off from the outside by the valve mechanism, and the opening part of the glove is attached to the part protruding from the outer case in the inner case. Then, the inside of the glove, the inside of the inner case, and the inside of the airtight case become a communication space and are disconnected from the outside.

  In this state, when the inner case is released from the rear side position of the outer case by the notch mechanism, the inner case is moved in a direction in which the inner case is pushed out within the slidable range in the outer case by the biasing mechanism. For this reason, the volume of the internal space of the airtight case is enlarged, and a negative pressure is formed in the airtight case. The airtight case and the inner case communicate with each other. As a result, a negative pressure is supplied to the inner side (the side not communicating with the outside air) of the glove that is airtightly attached to the opening of the inner case. Then, the gloves are sucked into the inner case and swell in the inner case. In this state, the wearer's hand can be easily inserted into the glove. If the hand is pushed in this state and the inner case is moved into the outer case, the negative pressure in the airtight case will decrease, and the pressure in the airtight case will change to positive pressure. Thus, the valve mechanism is automatically opened, the inside of the airtight case becomes the same as the outside air pressure, and the glove is in close contact with the wearer's hand. The wearer pulls his / her hand out of the inner case to finish the glove wearing operation.

The present invention can form a negative pressure inside the inner case by simply pushing the inner case into the outer case against the urging mechanism, and then releasing the state with the notch mechanism, and exhaust using a motor. A glove wearing device that does not require a mechanism can be provided.
Further, since it is not necessary to perform an operation for generating a negative pressure simultaneously with the insertion operation, the urging direction at the time of pushing in is not limited to the vertically downward direction, and can also be performed in an oblique direction. Then, a degree of freedom can be obtained in the direction of inserting the glove, and it can be directed obliquely downward for easy insertion.

It is a perspective view of a glove wearing apparatus. It is a partially broken top view of a glove wearing device. It is a partially broken side view of a glove wearing apparatus. It is a bottom view of a glove wearing apparatus. It is a partially broken front view of a glove wearing apparatus. It is a cross-sectional schematic diagram of the contact part of the gull wing and a slider in a glove wearing apparatus. It is sectional drawing which shows the attachment structure of the pin of the gull wing in a glove wearing apparatus. It is sectional drawing which shows the attachment structure of the pin of the gull wing in a glove wearing apparatus. It is sectional drawing which shows the attachment structure of the pin of the gull wing in a glove wearing apparatus. It is a partially broken top view of the glove wearing device concerning a modification. It is a partially broken side view of a glove wearing apparatus. It is a front view of a glove wearing apparatus. It is a principal part enlarged view of the airtight slide seal | sticker of a glove mounting apparatus.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a perspective view of a glove wearing device according to an embodiment of the present invention. Moreover, FIGS. 2-5 has shown each part by a partially broken figure.
In the figure, a support frame 20 serving as an outer case is fixed to the base plate 10, and a slider 30 serving as an inner case is supported by the support frame 20. Both the support frame 20 and the slider 30 have an oval cross section. The support frame 20 has a bottomed cylindrical shape, and the slider 30 has a cylindrical shape. Although the slider 30 also has a wall surface in the back of the cylinder and is close to a bottomed state, a vent hole 31 is formed in the back wall of the slider 30 and communicates with the internal space of the support frame 20. . A bellows 25 is disposed in the support frame 20. The bellows 25 communicates with the cylindrical slider 30 and expands and contracts when the slider 30 moves within a slidable range within the support frame 20. Specifically, the volume of the internal space increases when the slider 30 and the support frame 20 are separated from each other, and the volume of the internal space decreases when the slider 30 and the support frame 20 come close to each other. The bellows 25 corresponds to an airtight case.
On the other hand, the bellows 25 has a cylindrical shape with a bottom formed on a cylindrical body, and a bellows bottom portion opening hole 21 is formed on the wall surface on the back side, and an outer case is formed on the wall surface on the back side of the support frame 20 facing. An open hole 28 is formed. On the outer surface side of the support frame 20, a hinged valve 29 with a spring that communicates or shields the inside and the outside through a bellows bottom opening hole 21 and an outer case opening hole 28 is mounted. When the spring-loaded hinged valve 29 is opened, the inside and outside of the bellows 25 and the slider 30 communicate with each other. As will be described later, the spring-equipped hinged valve 29 in this embodiment has a positive pressure in the bellows 25 and the slider 30 when the slider 30 is pushed in (the pressure higher than the outside air is called the positive pressure, (When the pressure is low, it is called negative pressure.) Open and close at times other than positive pressure. The bellows bottom opening hole 21, the outer case opening hole 28, and the hinged valve 29 with a spring correspond to a valve mechanism for maintaining and releasing the positive pressure and the negative pressure in the airtight case.
Here, the support frame 20 corresponds to a bottomed cylindrical outer case, and the slider 30 is slidable with respect to the inner peripheral surface of the outer case, and is formed in a substantially cylindrical shape from the outer case. It corresponds to the inner case in which the opening part of the glove can be attached at the protruding part. Further, the bellows 25 and the slider 30 are in airtight communication with the inner space of the inner case, and the inner space and the outer case increase in volume when the inner case and the outer case are separated in the slidable range. This corresponds to an airtight case in which the volume of the internal space is reduced when the inner case and the outer case are close to each other.

  As shown in FIG. 1, the support frame 20 has a case shape extending downward from the side wall on the back side, and is fixed to the base plate 10 at the lower end. At this time, the support frame 20 is supported so as to be inclined so that the front side end portion is positioned higher than the rear side end portion with respect to the horizontal plane. Thereby, the attitude | position which makes it easy to insert a hand by the person who wears gloves can be hold | maintained.

  As shown in FIGS. 3 and 4, the outer peripheral shape of the slider 30 coincides with the inner peripheral surface shape of the support frame 20 to the extent that it can slide within a predetermined range in the length direction. The gap is formed so as to be as small as possible so that the airtightness can be sufficiently exhibited although it is not complete. In order to regulate the slidable range of the slider 30, two grooves (spring stroke travel guide grooves) 22, 22 are formed on the lower surface of the support frame 20 in parallel with the length direction. Are formed with slider-side spring fixing pins 32 and 32 protruding outward from the inside of the support frame 20.

  One ends of tension springs 33, 33 are locked to the slider-side spring fixing pins 32, 32, and the other ends of the tension springs 33, 33 are supported to protrude downward from the near side on the lower surface of the support frame 20. The frame-side spring fixing pins 23 are locked. The tension springs 33 and 33 urge the slider 30 to be pulled out toward the support frame 20, and the shape and length of the tension springs 33 and 33 can be pushed back into the support frame 20. It is determined by adjusting the size. In other words, the tension springs 33 and 33 do not sag in the movable range of the slider 30 even when the tension springs 33 and 33 are pulled to the near side with respect to the support frame 20, and push the slider 30 toward the back side with respect to the support frame 20. Even if it is in a position, it will not grow and lose its power.

  In this way, one end of the tension spring 33 is locked to the slider-side spring fixing pins 32, 32, and the other end is locked to the slider-side spring fixing pins 23, 23. The urging force is urged in the slidable range within the support frame 20 that is the outer case, and constitutes an urging mechanism.

  A one-way notch mechanism 24 is formed on the lower surface of the support frame 20. The one-way notch mechanism 24 is formed of a lever 24a, a pin 24b, a spring 24c, two plate-like support bracket portions 24d and 24d protruding downward, an opening 24e, and the like, and the lever 24a is provided with two plate-like supports. It is penetrated by the pin 24b while being sandwiched between the bracket portions 24d and 24d and is rotatably supported, and the spring 24c biases the front side of the lever 24a downward. As a result, the rear end of the lever 24a enters and abuts the inside of the support frame 20 through the opening 24e. A slider body notch slider recess 34 formed on the lower surface of the slider 30 is formed at the end of the contact. The slider recess 34 is formed at a predetermined position, and the tip of the lever 24a gets over the slider recess 34 when the slider 30 is pushed in, but is locked when the slider 30 tries to move in the reverse direction. When the end on the front side of the lever 24a is pulled up against the spring 24c, the engagement between the end on the back side of the lever 24a and the slider recess 34 is released, and the slider is moved by the urging force of the tension springs 33 and 33. 30 is a mechanism in which it is pulled back to the near side.

In this way, the one-way that enables the slider 30 as the inner case to be relatively held and released at the back side position of the support frame as the outer case against the urging mechanism constituted by the tension springs 33, 33 and the like. The notch mechanism 24 constitutes a notch mechanism.
In the present embodiment, the slider recess 34 is formed at a predetermined position. However, for example, a saw blade-shaped portion may be formed over a certain range so as to be locked at an arbitrary position. The configuration of the one-way notch mechanism 24 can be changed to other shapes that achieve the same purpose.

  As shown in FIG. 2, in this embodiment, since the spring stroke travel guide grooves 22 and 22 and the opening 24e are formed, the support frame 20 cannot hermetically isolate the inside and outside. For this reason, the inside of the bellows 25 is a substantial internal space of the support frame 20. The bellows 25 has a front side airtightly connected to a wall surface on the back side of the slider 30 and a rear side airtightly connected to a back wall of the support frame 20. That is, the bellows 25 itself has a bottomed cylindrical shape, and the front opening is connected to the cylindrical slider 30 to form a series of spaces that can be enlarged and reduced.

  The bellows 25 corresponds to a part of an airtight case that is disposed between the inner case and the outer case and has a stretchable and airtight property communicating with the inner case inner space.

  As shown in FIG. 2, a support frame side confirmation window 26 formed of a transparent plate on the upper surface is formed on the support frame 20 side, and a slider side confirmation window formed of a transparent plate on the upper surface is also formed on the slider 30 side. 36 is formed. When the slider 30 is pushed into the back side of the support frame 20, the support frame side confirmation window 26 and the slider side confirmation window 36 overlap each other so that the inside can be visually recognized through a transparent plate. Further, when the slider 30 is pushed out from the support frame 20 most, the slider side confirmation window 36 does not overlap the support frame 20, and the inside can be visually recognized only through the slider side confirmation window 36.

  As shown in FIGS. 2 to 5, a hook-like support frame side protrusion 27 extending in the length direction is formed on the inner peripheral surface on the opening side of the support frame 20, and the inner peripheral surface on the opening side of the slider 30. Grooves 37 extending in the length direction in which the support frame side protrusions 27 can enter are formed. When the slider 30 enters the inside of the support frame 20 most, the opening end of the slider 30 and the opening end of the support frame 20 are substantially flush with each other. As will be described later, the opening end of the slider 30 is covered with the opening end of the glove. The opening end portion (opening portion) of the glove does not enter the groove 37 due to its stretchability. However, in the process of pushing the slider 30 into the inside of the support frame 20, the support frame side protrusion 27 comes into contact with the end of the rubber glove that covers the groove 37. When further pushed in, the support frame side protrusion 27 gradually moves the end of the glove to the open end of the slider 30 and finally removes it from the slider 30. The support frame side protrusion 27 acts effectively because it does not bite into the gap between the slider 30 and the support frame 20 when the hand is pushed in.

  As shown in FIG. 5, the slider 30 is formed in a cylindrical shape, but the portion near the opening end is formed by dividing the wall surface. The cross section of the opening is generally an ellipse, and the upper surface side is formed integrally with the inner side of the cylinder. However, the lower surface side is divided into a pin-equipped gull wing 38a from the left curved surface to the lower straight portion and a pinless gull wing 38b from the right curved surface to the lower straight portion. The pin-equipped gull wing 38a and the pin-less gull wing 38b are also connected to the upper wall surface at the end of the curved surface by spring-loaded hinges 38a1 and 38b1, and can be rotated in the sectional plane of the open end. Since the hinges with springs 38a1 and 38b1 are biased in the direction in which the gull wings 38a with pins and the gull wings 38b without pins enter the inside of the opening, the end portion of the straight portion is normally the upper wall surface as shown in FIG. It is in the state close to. In this state, the outer peripheral length of the open end of the slider 30 becomes small. As will be described later, the opening end of the glove is put on the opening end of the slider 30, but the smaller the outer peripheral length, the smaller the opening end of the glove is, and the easier the operation becomes.

  If the pin-equipped gull wing 38a and the pin-less gull wing 38b are pushed and spread against the spring hinges 38a1 and 38b1, the opening end of the slider 30 has the same shape as the cylindrical portion on the back side. At this time, as shown in FIG. 6, the edges of the pin-equipped gull wings 38 a and the pinless gull wings 38 b are pressed inside the edges of the slider 30. A gull wing seal 38c is affixed to this portion, and it is easy to ensure airtightness when pressed.

As shown in FIGS. 7 and 8, a pin 38d movable in the length direction is accommodated in the end portion of the pin-attached gull wing 38a. The tip of the pin 38d is internally biased so as to protrude toward the rear side.
A through hole 38d1 that substantially coincides with the depth direction of the slider 30 is formed inside the wall material at the end of the pin-attached gull wing 38a. In the through hole 38d1, a pin 38d having a tapered tip and a spring 38d2 is accommodated, and the pin 38d is connected by a screw 38d4 and an operator 38d5 through a long hole 38d3 communicating with the outer peripheral surface of the pin-attached gull wing 38a. The front side is sealed in the through hole 38d1, and the spring 38d2 is accommodated on the sealed side, so that the spring 38d2 biases the pin 38d in a pushing direction.

  However, since the screw 38d4 connected to the pin 38d can move only within the range of the length of the long hole 38d3, the pin 38d is not completely pushed out of the through hole 38d1, and only the tip as shown in FIG. It protrudes and is in a state where the remaining part is always held in the through hole 38d1. Further, as shown in FIG. 8, the pin 38d can be pulled back into the through hole 38d1 within the range of the length of the long hole 38d3. When it is desired to release the lock, the operating element 38d5 is operated to pull the pin 38d back into the through hole 38d1.

  The tip of the pin 38d is an inclined surface, and this inclined surface is located in front of the hole 38d6 formed in the wall surface on the upper surface of the slider 30, as shown in FIG. When it comes into contact with the formed slope 38d7, it is guided to be pushed into the through hole 38d1. Once over the slope 38d7 and facing the hole 38d6, the tip of the pin 38d enters the hole 38d6 by the biasing force of the spring 38d2, and the pin-attached gull wing 38a can be locked to the wall surface of the upper surface of the slider 30. In a state where the pin-equipped gull wing 38a and the wall surface of the slider 30 are locked, the slider 30 is prohibited from returning from the position of the expanded diameter state to the reduced diameter state.

In this way, the cylindrical peripheral wall surface is divided in the vicinity of the end in the longitudinal direction of the inner case which is the slider 30 (gull wing 38a with pin and gull wing 38b without pin), and rotates parallel to the length direction as the cylindrical body. It has a shaft (spring hinges 38a1 and 38b1), and the peripheral wall surface is rotatable inward with the rotation shaft as a support shaft.
As a result, the portion of the inner case protruding from the outer case is a cylindrical shape having a longitudinal direction and a short direction, and the thickness length can be changed in the short direction.
At the opening end of the slider 30, a glove is pulled in and a non-slip prevention 41 is attached. This is to prevent the entire glove from being pulled more than necessary when the entire glove is pulled inside the slider 30 after the glove is attached to cover the opening end of the slider 30 as will be described later. Note that leakage of negative pressure is reduced by making it difficult to form a gap when the glove is attached to cover the opening end of the slider 30.

  In this embodiment, the opening end of the slider 30 is divided into a wall surface on the upper surface side and a wall surface on the lower surface side, and the wall surface on the lower surface side is deformed, so that the portion protruding from the outer case in the inner case has a narrow opening width. It is configured as an opening width adjusting mechanism that changes between a reduced diameter state and an enlarged diameter state with a wide opening width. However, it is also possible to divide the opening end of the slider 30 in the longitudinal direction and to deform so that one of them slides in the longitudinal direction to widen or narrow the opening width. Further, although the pin 38d of the gull wing 38a with the pin is locked in the hole 38d6, it goes without saying that the same function can be configured by another locking mechanism.

  In the above configuration, in the operation of wearing a glove made of rubber, resin, or the like, as shown on the upper side of FIG. In this state, the operator pushes the slider 30 into the back side of the support frame 20. When the slider 30 is pushed in most against the tension springs 33, 33, the tip of the lever 24 a in the one-way notch mechanism 24 is locked to the slider recess 34. At this time, the opening end of the slider 30 protrudes from the opening end of the support frame 20.

  Next, the operator covers the opening end of the slider 30 while extending the opening end of the glove to the left and right. Since the gull wing 38a with pin and the gull wing 38b without a pin at the opening end of the slider 30 are not in a diameter-expanded state, the length required to widen the opening end of the glove can be shortened. Easy to install. When the opening end of the glove can be covered, the pin-attached gull wing 38a is pushed down from the outside of the glove with the fingertip. The pin-attached gull wing 38a is formed longer than the pin-less gull wing 38b, and as shown in FIG. 5, the tip of the pin-attached gull wing 38a enters inside the tip of the pin-less gull wing 38b.

  Accordingly, the pin-equipped gull wing 38a is pushed down with the fingertip. The tip of the pin-equipped gull wing 38a also pushes the tip of the pin-less gull wing 38b downward from the inside, and both the pin-equipped gull wing 38a and the pin-less gull wing 38b move downward and form a wall surface similar to the wall on the upper surface side. It leads to. Of course, by this operation, the outer peripheral length of the opening end of the slider 30 gradually increases, and the opening end of the glove is also spread from the inside. When the tip of the pin-attached gull wing 38a overlaps the wall surface at the back of the slider 30, the pin 38d enters the hole 38d6 and is locked as described above. As a result, the pin-equipped gull wing 38a and the pin-less gull wing 38b have substantially the same cross-sectional shape as the wall surface on the upper surface side, and the slider 30 forms the same circumferential surface as that of the inner cylinder.

In this state, the internal space of the bellows 25 in the support frame 20 and the internal space of the slider 30 are in communication with each other. Furthermore, since the glove is put on the opening end of the slider 30, the space is an airtightly closed space.
Next, when the front side of the lever 24 a of the one-way notch mechanism 24 is pulled up, the tip of the lever 24 a is detached from the slider recess 34. Then, the slider 30 is driven in a direction to be pushed out from the support frame 20 by the urging force of the tension springs 33 and 33. Since this movement enlarges the internal space of the bellows 25 in the support frame 20 and the internal space of the slider 30, negative pressure is generated inside. The glove placed on the open end of the slider 30 is pulled by the pressure of the outside air due to the negative pressure inside, and further inflates according to the negative pressure. However, since the glove is pulled into the opening end of the slider 30 and the anti-skid 41 is attached, the glove is prevented from being pulled out of the opening end of the slider 30 even if it is pulled inside the slider 30. it can. When the negative pressure is generated, the bellows bottom opening hole 21 is closed and the negative pressure is maintained.

  The operator inserts his hand through the open end of the glove when in the swollen state. Since the glove is swollen in the slider 30, the operator can easily insert the fingertip into the glove. Even if gloves are worn on the fingertips, the user still pushes his hand. Then, since the fingertip hits the inner wall surface in the slider 30, the slider 30 is further pushed in with the fingertip. This movement reduces the internal space of the bellows 25 in the support frame 20 and the internal space of the slider 30, so that the internal negative pressure decreases and the glove fits the operator's hand. . Further, since the opening end of the slider 30 enters the opening end of the support frame 20, the support frame side protrusion 27 starts to contact the end of the rubber glove that covers the groove 37 and further presses. The support frame side protrusion 27 gradually moves the end of the glove to the opening end of the slider 30 and finally removes it from the slider 30.

  When the rubber glove at the opening end of the slider 30 is removed, the internal space of the bellows 25 in the support frame 20 and the internal space of the slider 30 communicate with the outside air. Although the slider 30 is sufficiently pushed into the support frame 20, the slider 30 gradually returns to the near side when the operator begins to pull out the hand. However, as described above, the lever 24a of the one-way notch mechanism 24 stops at the position where the lever 24a is engaged with the slider recess 34.

Thereafter, at this position, the operation is resumed from the operation of putting the glove on the open end of the slider 30 again.
As described above, the present invention has developed a small and lightweight “manual glove wearing device” that can be easily used by anyone without using any power unit that requires a power source.
The main driving force of this device is a “tension coil spring”. After the negative pressure is created by the repulsive force of the tension spring 33 and the gloves are adsorbed, the adsorbed state is maintained for a long time by sealing securely so that outside air does not enter into the negative pressure part mainly between the components constituting the device. The
The tension springs 33 and 33 are disposed on the lower surface side outside of the support frame 20, and are formed as compression springs 33 a and 33 a indicated by two-dot chain lines in FIG. 2 inside the support frame 20. You may make it urge in the direction which pushes out the slider 30 with respect to the support frame 20 using repulsion.

After the hand is inserted, the opening end of the slider is pushed by the support frame side projection 27 at the end of the support frame 20 by pushing it into the back until the glove is removed while resisting the reaction force of the tension spring 33. It is automatically removed by moving inward from the tip of the open end of 20.
At this time, the one-way notch mechanism 24 is not engaged. When the hand is pulled out from the slider 30 with the gloves on, the slider 30 is automatically notched by a one-way notch mechanism provided on the support frame 20. (The tension spring 33 remains in tension)

After the next glove is set at the open end of the slider 30, if the one-way notch mechanism 24 is removed with the fingertip, the tension spring 33 is released, and the slider 30 body is slid at once and the set glove is attracted to the inner surface of the slider 30 (glove expansion) ) To return to the first operation.
The whole is small and light, so it is easy to handle and can be used with simple operations.
Since the support frame side confirmation window 26 and the slider side confirmation window (transparent / blocking) 36 are provided, the state of the glove can be seen from the outside and can be relieved.

  The lower half of the exposed end of the slider 30 is divided into left and right gull wings. Gull wing with pin 38a and gull wing 38b without pin swing in the vertical direction in the figure, and the circumferential length decreases, so it is easy to set the glove at the tip, and the gull wing is pushed down to the original position with the fingertip and the fitting part It is possible to perform reliable operation while maintaining the sealing performance. In the one-way notch mechanism 24, the tip of the lever 24a is always pushed up by the spring 24c, the tip of the notch lever 24a contacts and slides on the outer surface of the slider 30, and automatically falls into the recess formed in the slider 30. Can be fixed. Then, by pulling the lever 24a, the slider 30 slides at a stroke and the glove is attracted to the inner surface of the holder.

  The normal position of the end portion of the slider 30 is a position where it is pushed into the support frame 20, and the tension spring 33 at this time remains in a tensioned state. The length of the bellows 25 is also short. At this time, the glove is set at the opening end of the slider 30 and the lever 24a is pulled forward so as to remove the one-way notch mechanism 24 from the slider recess 34, so that the slider 30 has a reduced spring force in the support frame 20 at a stretch. By sliding until it is released and the bellows 25 is extended at the same time, the entire inside of the slider 30 is also brought to a negative pressure, and the glove is dragged in and adsorbed to the inner wall surface side of the slider 30.

  The negative pressure generated in the bellows 25 passes through the vent 31 and becomes negative throughout. The end on the back side of the bellows 25 is supported by the bellows fixing portion with respect to the wall on the back side of the support frame 20.

  The gull wing structure at the tip of the slider 30 is for shortening the circumferential length so that it can be worn as easily as possible when wearing gloves. The left and right lengths are changed so that the gull wings 38a and 38b can be set with one touch of one hand. The gull wings 38a and 38b use spring-attached hinges 38a1 and 38b1 as attachment portions, and their operations are fixed by a gull wing pin 38d. The diagonally aligned portions of the ends of the gull wings 38a and 38b are sealed with thin rubber or the like. When the pin 38d is disengaged from the hole 38d6, the gull wings 38a and 38b jump up so as to be held by the spring-loaded hinges 38a1 and 38b1.

The tip end surface portion of the opening end of the slider 30 and the tip end surface portion on the opening end side of the gull wing are both formed into a sheet having an uneven surface or an uneven shape, so that when a glove is inhaled, it is easily dragged deep inside. It is made not to be inserted.
The performance of this device is affected by the sealing of movable parts such as Gullwing and connecting parts. The smaller the air suction leak, the longer the glove can remain expanded (adsorbed). Therefore, it is preferable that all the mating portions have a sealing structure (such as a thin rubber plate).

  Further, when the hand is inserted into the enlarged glove and is pushed together with the slider 30, it is easy to apply a force. Therefore, if the pushing bar-shaped protrusion 39 is formed on the inner surface of the slider 30, the hand can be pushed and pushed easily. be able to.

  In this embodiment, the support frame 20 that is the outer case is fixed to the base plate 10 that is the base, and the slider 30 that is the inner case is slidable with respect to the outer case.

  In this embodiment, a bellows 25 is used. However, the tension springs 33, 33 can be replaced with compression springs 33 a, 33 a so as to be accommodated between the inside of the support frame 20 and the slider 30. Further, if the inside and outside of the support frame 20 are not communicated with each other by the spring stroke travel guide grooves 22, 22, the bellows 25 need not be used. Since the one-way notch mechanism 24 is attached to the front side of the lower surface of the support frame 20, the slider 30 and the support frame 20 may always overlap with each other, and the opening 24 e makes the support frame 20 and the slider 30 airtight. It does not affect. In this way, the inner case can be slid in an airtight manner with respect to the inner peripheral surface of the outer case, and the outer case is formed in an airtight manner, so that the bellows is substantially unnecessary as the airtight case. Is possible.

Therefore, sliding the support frame 20 and the slider 30 generates a negative pressure inside to enlarge the glove, and the method of wearing it is structurally as described above (FIG. 4) with the bellows-type tension springs 33 and 33, ( FIG. 2) There are three methods: the bellows compression springs 33a and 33a and the bellowsless compression springs 33a and 33a.
10 to 12 show the parts of the glove wearing device according to the modification in a partially broken state, FIG. 10 is a partially broken top view, and FIG. 11 is a partially broken side view. 12 is a front view.

In each figure, a support frame 120 serving as an outer case is fixed to the base plate 110, and a slider 130 serving as an inner case is supported by the support frame 120. Both the support frame 120 and the slider 130 have an oval cross section. The support frame 120 has a bottomed cylindrical shape, and the slider 130 has a cylindrical shape. The slider 130 is also bottomed by forming a wall surface behind the cylinder.
The outer shape of the slider 130 and the inner peripheral shape of the support frame 120 can be brought close to and away from each other while forming a slight gap therebetween, and can be said to constitute a so-called piston and cylinder.

  Further, as shown in FIG. 13, in order to improve the airtightness, an annular groove 130a is formed on the outer peripheral surface of the back side of the slider 130, and the annular groove 130a has a ring shape. An airtight slide seal 125a is attached. The airtight slide seal 125a is interposed between the outer peripheral surface of the slider 130 and the inner peripheral surface of the support frame 120 to improve the airtightness. On the other hand, the airtight slide seal 125a is formed of a material having low sliding resistance so that the sliding resistance between the slider 130 and the support frame 120 does not increase.

Note that the support frame-side protrusion 127 is formed on the support frame 120 side and the groove 137 is formed on the slider 130 side, which is the same as in the above-described embodiment.
A slider open hole 128b is formed in the wall surface in the back of the slider 130, and the internal space of the slider 130 and the internal space of the support frame 120 communicate with each other. However, with respect to the slider opening hole 128b, a valve 129b with a restoring function is mounted on the inner space side of the support frame 120, and when the valve 129b with the restoring function is opened, the inner space of the support frame 120 and the slider 130 Communication with the internal space.

Further, the flow of air is blocked from the internal space of the support frame 20 toward the internal space of the slider 130, and the flow of air is blocked from the internal space of the slider 130 toward the internal space of the support frame 20. Not to be.
The support frame 20 also has a bottomed cylindrical shape with a bottom formed on a cylindrical body, and an outer case opening hole 128a is formed on the inner wall surface. On the outer surface side of the support frame 120, a valve 129 a with a restoring function that communicates or shields the inside and the outside through the outer case opening hole 128 a is mounted. When the valve 129a with the restoring function is opened, the internal space of the support frame 120 communicates with the outside.

  In the present embodiment, the valve 129a with a restoring function opens when the slider 130 is pushed and the inside of the support frame 120 becomes a positive pressure, and closes at a time other than the positive pressure. The outer case opening hole 128a and the restoring function-equipped valve 129a correspond to a valve mechanism that maintains and releases the positive pressure and the negative pressure in the airtight case. Further, the restoring function-equipped valve 129b is hermetically closed when the slider 130 is pushed in and the inside of the support frame 120 becomes positive pressure, and is not airtight at times other than positive pressure. For example, when it becomes negative pressure, it opens, and when it becomes almost the same pressure, it closes in a state where the airtightness cannot be maintained. The slider opening hole 128b and the restoring function-equipped valve 129b correspond to a valve mechanism that maintains and releases the positive pressure and the negative pressure in the airtight case. When the slider 130 is pushed in, the restoring valve 129b is closed, the restoring function valve 129a is opened, the air in the space formed by the support frame 120 and the slider 130 is pushed out, and when the slider 130 is pulled, the restoring function is provided. The valve 129a is closed, the restoring function valve 129b is opened, and if the glove is attached to the opening of the slider 130, the space inside the support frame 120 and the slider 130 is decompressed.

  Here, the support frame 120 corresponds to a bottomed cylindrical outer case, and the slider 130 is slidable with respect to the inner peripheral surface of the outer case, and is formed in a substantially cylindrical shape from the outer case. It corresponds to the inner case in which the opening part of the glove can be attached at the protruding part. Further, the support frame 120 and the slider 130 are in airtight communication with the inner space of the inner case, and the volume of the inner space increases when the inner case and the outer case are separated in the slidable range, This corresponds to an airtight case in which the volume of the internal space is reduced when the inner case and the outer case are close to each other. That is, the airtight case is configured without using the bellows 25.

  A compression spring 133 is interposed between the inner wall (inner bottom surface) on the inner peripheral surface side of the support frame 20 and the inner wall surface (outer bottom surface) on the outer peripheral surface side of the slider 130, and the compression spring 133 is supported by the support frame. An urging force is generated in the direction of pushing out the slider 130 from the 120 side. Although the two compression springs 133 are attached in the drawing, for example, the compression spring 133 may be formed of one elliptical coil spring that is similar in shape to the back wall surface of the slider 130 and slightly smaller. The compression spring 133 corresponds to a biasing mechanism that biases the inner case in a direction in which the inner case is pushed out within a slidable range within the outer case.

  A one-way notch mechanism 124 is formed on the lower surface of the support frame 120. The one-way notch mechanism 124 is formed of a lever 124a, a pin 124b, a spring 124c, two plate-like support bracket portions 124d and 124d protruding downward, an opening 124e, and the like. The lever 124a is provided with two plate-like supports. In a state sandwiched between the bracket portions 124d and 124d, the pin 124b penetrates and is rotatably supported, and the spring 124c biases the front side of the lever 124a downward. As a result, the rear end of the lever 124a enters and abuts the inside of the support frame 120 through the opening 124e. A slider body notch slider recess 134 formed on the lower surface of the slider 130 is formed at the end of the contact. The slider recess 134 is formed at a predetermined position, and the tip of the lever 124a gets over the slider recess 134 when the slider 130 is pushed in, but is locked when the slider 30 tries to move in the reverse direction. When the end on the front side of the lever 124a is pulled up against the spring 124c, the engagement between the end on the back side of the lever 124a and the slider recess 34 is released, and the slider 130 is moved by the urging force of the compression spring 133. It is a mechanism that is pulled back to the near side.

Note that the above-described gull wing structure portion is not formed at the opening end of the slider 130. Although the circumferential length cannot be shortened when wearing gloves, the structure becomes simple and the airtightness of the peripheral wall surface of the slider 130 can be improved.
In the above configuration, in the operation of wearing a glove made of rubber, resin, or the like, the slider 130 itself starts from the state where it protrudes most from the support frame 120 as shown in the upper side of FIG. In this state, the operator pushes the slider 130 into the back side of the support frame 120. When the slider 130 is pushed in most against the compression spring 133, the tip of the lever 124 a in the one-way notch mechanism 124 is engaged with the slider recess 134. At this time, the open end of the slider 130 protrudes beyond the open end of the support frame 120.

  Next, the operator covers the opening end of the slider 130 while extending the opening end of the glove to the left and right. In this state, both the internal space in the support frame 120 and the internal space of the slider 130 are in a normal atmospheric pressure state, and the valves 129a and 129b with a restoring function are closed. Further, since the opening end of the slider 130 is covered with gloves, the internal space in the support frame 120 and the internal space of the slider 130 are airtightly closed.

  Next, when the front side of the lever 124 a of the one-way notch mechanism 124 is pulled up, the tip of the lever 124 a is detached from the slider recess 134. Then, the slider 130 is driven in a direction to be pushed out from the support frame 120 by the urging force of the compression spring 133. Since this movement enlarges the internal space of the support frame 120 and the internal space of the slider 130, negative pressure is generated inside. However, while the valve 129a with the restoring function is closed and tries to hold the negative pressure, the valve 129b with the restoring function is opened so that the inner space of the support frame 120 and the inner space of the slider 130 have almost the same negative pressure. To. Thereafter, the restoring function valve 129 b functions so that the negative pressure in the inner space of the slider 130 does not flow backward to the inner space side of the support frame 120. Thereby, the negative pressure inside the slider 130 can expand the glove for a long time.

  The glove placed on the opening end of the slider 130 is pushed by the atmospheric pressure and drawn into the slider 130 mainly due to the negative pressure inside the slider 130, and further expands according to the negative pressure. . However, the anti-skid 141 for preventing the gloves from being pulled in is attached to the opening end of the slider 130, and even if the entire glove is pulled into the inside of the slider 130, it can be prevented from being pulled out of the opening end of the slider 130. .

  The operator inserts his hand through the open end of the glove when in the swollen state. Since the glove is swollen in the slider 130, the operator can easily insert the fingertip into the glove. Even if gloves are worn on the fingertips, the user still pushes his hand. A pushing bar-like protrusion 139 that protrudes toward the inner circumference and expands in the width direction is formed at the back of the inner circumferential surface of the slider 130, and the fingertip abuts against the pushing bar-like protrusion 139 in the slider 130. Then push the slider 130 in. Since this movement reduces the internal space of the support frame 120 and the internal space of the slider 130, the negative pressure inside the support frame 120 decreases, but on the other hand, the negative space in the internal space of the slider 130 decreases. Pressure is maintained. Further, since the opening end of the slider 130 enters the opening end of the support frame 120, the support frame-side protrusion 127 starts to contact the end portion of the rubber glove that covers the groove 137, and further pushes in. The support frame side protrusion 127 gradually moves the end of the glove to the opening end of the slider 130 and finally removes it from the slider 130.

When the rubber gloves at the opening end of the slider 130 are removed, the internal space of the slider 130 communicates with the outside air. Although the slider 130 is sufficiently pushed into the support frame 120, the slider 130 gradually returns to the near side when the operator begins to pull out the hand. However, as described above, the lever 124a of the one-way notch mechanism 124 stops at a position where the lever 124a is engaged with the slider recess 134.
Thereafter, at this position, the operation of putting the gloves on the opening end of the slider 130 is resumed.

In this way, the compression spring 133 is compressed inside the support frame 120 to form a thrust structure that pushes out the slider 130. By making the slider opening hole 128b larger than the outer case opening hole 128a larger, the glove can be easily dragged into the back of the slider 130 due to the instantaneously generated negative pressure and can be expanded. The valves 129a and 129b with a restoring function can be substituted with a rubber sheet or the like. For example, the same function can be achieved by adhering only the vicinity of one piece of a rectangular rubber sheet.
In addition, about the valve | bulb with a restoring function, it forms with the one-way valve mechanism which opens and closes largely.

Needless to say, the present invention is not limited to the above embodiments. It goes without saying for those skilled in the art,
・ Applying mutually interchangeable members and configurations disclosed in the above embodiments by appropriately changing the combination thereof.− Although not disclosed in the above embodiments, it is a publicly known technique and the above embodiments. The members and configurations that can be mutually replaced with the members and configurations disclosed in the above are appropriately replaced, and the combination is changed and applied. It is an embodiment of the present invention that a person skilled in the art can appropriately replace the members and configurations that can be assumed as substitutes for the members and configurations disclosed in the above-described embodiments, and change the combinations and apply them. It is disclosed as.

DESCRIPTION OF SYMBOLS 10 ... Base plate, 20 ... Support frame, 21 ... Bellows bottom opening hole, 22 ... Spring stroke travel guide groove, 23 ... Support frame side spring fixing pin, 24 ... One-way notch mechanism, 24a ... Lever, 24b ... Pin, 24c ... Spring, 24d ... Support bracket part, 24e ... Opening part, 25 ... Bellows, 26 ... Support frame side release confirmation window, 27 ... Support frame side protrusion, 28 ... Outer case opening hole, 29 ... Spring hinge valve 30 ... Slider, 31 ... Vent, 32 ... Slider side spring fixing pin, 33 ... Tension spring, 33a ... Compression spring, 34 ... Slider recess, 36 ... Slider side sealing confirmation window, 37 ... Groove, 38a ... Gull wing with pin, 38a1 ... Spring hinge, 38b ... No pin gull wing, 38b1 ... Spring hinge, 38c ... Gull wing Seal, 38d ... Pin, 38d1 ... Through hole, 38d2 ... Spring, 38d3 ... Elongated hole, 38d4 ... Screw, 38d5 ... Operator, 38d6 ... Hole, 38d7 ... Slope, 39 ... Pushing protrusion, 41 ... Prevention of pull-in Non-slip 110, base plate, 120 ... support frame, 124 ... one-way notch mechanism, 124a ... lever, 124b ... pin, 124c ... spring, 124d ... support bracket, 124e ... opening, 125a ... airtight slide seal, 127 ... Support frame side protrusion, 128a ... outer case opening hole, 128b ... slider opening hole, 129a ... valve with restoring function, 129b ... valve with restoring function, 130 ... slider, 130a ... annular groove, 133 ... compression spring, 134 ... slider recess 137... Groove, 139. 41 ... Anti-skid to prevent being pulled in.

Claims (9)

A bottomed cylindrical outer case,
An inner case that is slidable with respect to the inner peripheral surface of the outer case, and that can be attached to an opening part of a glove at a part that is formed in a substantially cylindrical shape and protrudes from the outer case;
An urging mechanism for urging the inner case in a direction in which the inner case is pushed within a slidable range in the outer case;
When the inner case and the outer case are separated from each other within the slidable range, the volume of the inner space increases, and the inner case and the outer case are close to each other. Then the airtight case where the volume of the internal space is reduced,
A notch mechanism that holds and releases the inner case relative to the biasing mechanism at a position on the back side of the outer case;
A glove wearing device comprising: a valve mechanism for maintaining and releasing positive pressure and negative pressure in the airtight case.   2. The glove wearing device according to claim 1, wherein the airtight case has an expandable and airtight bellows communicating with the inner case inner space between the inner case and the outer case.   2. The airtight case according to claim 1, wherein the inner case is configured to be airtightly slidable with respect to an inner peripheral surface of the outer case, and the outer case is formed to be airtight. Glove wearing device.   The portion of the inner case protruding from the outer case includes an opening width adjusting mechanism that changes into a reduced diameter state with a narrow opening width and an expanded state with a wide opening width. The glove wearing apparatus in any one.   The opening width adjusting mechanism has a configuration in which a portion protruding from the outer case in the inner case has a cylindrical shape having a longitudinal direction and a short direction, and the thickness length can be changed in the short direction. The glove wearing device according to claim 4.   6. The glove wearing device according to claim 1, wherein the outer case is fixed to a base, and the inner case is slidable with respect to the outer case.   7. The glove wearing device according to claim 1, wherein the urging mechanism performs the urging with a compression spring.   The glove wearing apparatus according to claim 1, wherein the urging mechanism performs the urging with a tension spring.   4. The glove wearing device according to claim 3, wherein an annular airtight seal member is interposed between the outer peripheral surface of the inner case and the inner peripheral surface of the outer case.

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