阅读说明：本技术 安全针装置 (Safety needle device ) 是由 M·寇莫达 M·尼米艾克 R·格热拉克 R·奥沙伊亚克 R·珀尔 B·毕亚瓦斯 于 2021-05-26 设计创作，主要内容包括：安全针装置(1),包括：针座(10)；安装于针座(10)的针(20),针(20)沿着纵向轴线(X-X)在形成用于插入患者体内的远端(21)和形成为连接至容器的相反的近端(22)之间延伸；保护罩(30),其可沿着纵向轴线(X-X)相对于针座(10)滑动并被围绕纵向轴线(X-X)旋转约束；壳体(40),其安装于针座(10)；弹性构件(50),其配置在壳体(40)内并作用于保护罩(30)；套筒(60),其配置在壳体(40)内并可相对于保护罩(30)和壳体(40)围绕纵向轴线旋转地安装；锁定布置结构(70),其包括第一锁定构件(71)和第二锁定构件(72)；安全针装置(1)包括引导布置结构(80)。(Safety needle device (1) comprising: a needle seat (10); a needle (20) mounted to the needle hub (10), the needle (20) extending along a longitudinal axis (X-X) between a distal end (21) formed for insertion into a patient and an opposite proximal end (22) formed for connection to a container; a protective shield (30) slidable relative to the needle hub (10) along a longitudinal axis (X-X) and constrained in rotation about the longitudinal axis (X-X); a housing (40) attached to the hub (10); an elastic member (50) which is disposed in the housing (40) and acts on the protective cover (30); a sleeve (60) arranged within the housing (40) and rotatably mounted relative to the protective cover (30) and the housing (40) about a longitudinal axis; a locking arrangement (70) comprising a first locking member (71) and a second locking member (72); the safety needle device (1) comprises a guiding arrangement (80).)

1. A safety needle device, comprising:

-a needle hub configured to be connected to a container,

-a needle attached to the needle hub, the needle extending along a longitudinal axis between a distal end configured for insertion into a patient and an opposite proximal end configured for connection to the container,

-a protective shield slidable relative to the hub along the longitudinal axis and rotationally constrained about the longitudinal axis, the protective shield being irreversibly slidable from an initial position before injection through an intermediate position to a locked position after injection,

-a housing attached to the needle hub and enclosing:

-a portion of the needle hub;

-a portion of the protective cover when the protective cover is in an initial position and in a locked position;

-when the protective cover is in the intermediate position, substantially all of the protective cover,

-a resilient member arranged within the housing and acting on the shield, the resilient member being biased to urge the shield towards the distal end of the needle in contrast to a longitudinal sliding of the shield towards the proximal end of the needle,

a sleeve arranged within the housing and rotatably mounted relative to the boot and the housing about the longitudinal axis,

-a locking arrangement comprising at least one first locking member formed on the boot and at least one second locking member formed on the sleeve, the first locking member cooperating with the second locking member to:

-rotating the sleeve while the boot is sliding to guide the boot from an initial position to a locked position; and

-locking the protective cover in the locked position when the locked position is reached,

wherein

-the protective cover encloses:

-at least part of the sleeve when the protective cover is in the initial position and in the locked position;

-when the protective cover is in the intermediate position, substantially all of the sleeve,

and

-the safety needle device comprises a guiding arrangement comprising a first guiding member formed on the protective shield and a second guiding member formed on the housing, the first guiding member cooperating with the second guiding member to guide the protective shield to slide along the longitudinal axis and to prevent the protective shield from rotating relative to the housing.

2. The safety needle device of claim 1, wherein:

-the housing has an inner surface facing at least partially the sleeve and the protective cover and an opposite outer surface;

-the protective cover has an outer surface facing at least partially the inner surface of the housing and an inner surface facing at least partially the sleeve;

-the sleeve has an inner surface facing at least partially the hub and an opposite outer surface facing at least partially an inner surface of the protective cover and an inner surface of the housing.

3. The safety needle device of claim 2, wherein:

-the first guide member is formed at the outer surface of the protective cover;

-the second guide member is formed on the inner surface of the housing.

4. The safety needle device of claim 2, wherein:

-the second guide member comprises a longitudinal groove formed in the inner surface of the housing;

-the first guide member comprises a protrusion protruding from the outer surface of the boot and configured to engage with the longitudinal groove.

5. The safety needle device of claim 2, wherein:

-the first guide members are angularly spaced apart on the outer surface of the boot;

-the second guide members are angularly spaced apart on the inner surface of the housing.

6. The safety needle device of claim 2, wherein:

-the first locking member is formed on the inner surface of the boot;

-the second locking member is formed on the outer surface of the sleeve.

7. The safety needle device of claim 6, wherein:

-the second locking member comprises a slit;

-the first locking member comprises a pin configured to engage with the slit.

8. The safety needle device of claim 7, wherein the slit comprises:

-a first stop segment configured to engage with the pin in an initial position of the shield to prevent longitudinal sliding of the shield towards the distal end of the needle;

-a second stop segment configured to engage with the pin in an intermediate position of the shield to prevent longitudinal sliding of the shield towards the proximal end of the needle;

-a locking section configured to engage with the pin in a locked position of the boot to prevent longitudinal sliding of the boot towards both the distal and proximal ends of the needle.

9. The safety needle device of claim 7, wherein the slit comprises:

a first rotation section configured to engage with the pin and rotate the sleeve when the boot slides along the longitudinal axis from an initial position towards an intermediate position,

-a second rotational segment configured to engage with the pin and rotate the sleeve when the boot slides along the longitudinal axis from a neutral position towards a locked position.

10. The safety needle device of claim 2, wherein:

-the resilient member surrounds at least part of the outer surface of the sleeve, the resilient member being interposed between the needle hub and the protective cover.

11. The safety needle device as recited in claim 10, wherein:

-the elastic member extends along the longitudinal axis between a distal portion and a proximal portion,

-the hub comprises a stop wall configured to receive a proximal portion of the resilient member;

-the boot comprises an annular flange protruding from the inner surface of the boot and configured to retain a distal portion of the resilient member.

12. The safety needle device of claim 1, wherein the protective shield includes a logo on an outer surface thereof, the logo configured to be visible only when the protective shield is in the locked position.

Technical Field

The present invention relates to the technical field of medical devices, in particular to a protection device capable of preventing accidental or intentional injury to a user by a needle before and after an injection.

Background

Generally, the safety needle device comprises an elongate needle having a first end insertable into the skin of a patient and a second end insertable into a receptacle for supplying a substance. The needle is embedded in the needle mount and partially enclosed by a housing secured to the needle mount. The known device also comprises a protective shield surrounding and moving along the needle. The first end of the protective cover points to the outside of the housing and the second end moves inside the housing and points to the needle hub. A spring is disposed between the shield and the hub such that the shield is constantly urged toward the first end of the needle. Specifically, during injection, the shield is urged within the housing toward the second end of the needle, thereby compressing the spring, which then urges the shield toward the first end of the needle during withdrawal of the needle from the patient. To prevent further use or injury, the device comprises locking means capable of locking the sliding of the protective cover after injection.

An example of a safety needle device is disclosed in patent application WO2019156579a1 in the name of the applicant. Such devices include a rotating sleeve inside the housing that at least partially surrounds the needle. In particular, the protective cover and the rotating sleeve cooperate in order to lock the protective cover against further use or injury. In detail, at least the second end of the protective cover is inserted into the rotating sleeve, and a pin protruding from an outer surface of the protective cover is engaged with a groove formed in the rotating sleeve. Initially, the pin is configured in a first span (bay) formed in the slot, the first span allowing longitudinal movement of the boot. During injection, the protective cap slides within the rotating sleeve, causing a first rotation of the sleeve, and then during withdrawal, the protective cap is pushed at least partially outside the sleeve by the spring, causing a second rotation of the sleeve. This rotation allows the pin to be routed from the first span to the second span, locking the pin against further longitudinal movement of the protective cover.

However, known safety needle devices exhibit some disadvantages. In fact, such devices do not ensure proper protection of the user from further use and accidental injury. Furthermore, the known devices are complex and require many components to achieve the result, which increases the overall cost of production and design.

It should also be noted that the device for preventing rotation of the boot during injection disclosed in WO2019156579a1 has a rib formed on the hub which is engaged by the boot as it enters the rotating sleeve during injection. If improperly aligned with the corresponding grooves on the boot, the ribs prevent longitudinal movement of the boot, rendering the device unusable.

Disclosure of Invention

In this context, the underlying technical task of the present invention is to propose a safety needle device which overcomes the drawbacks of the prior art described above.

In particular, it is an object of the present invention to provide a safety needle device which is able to ensure protection for the user and at the same time improve the usability of the device itself.

The technical task and the specific objects set forth are substantially achieved by a protective cover interposed between the housing and the sleeve surrounding the needle hub.

Drawings

The present invention will now be described more fully hereinafter with reference to the accompanying drawings, in which some embodiments of the invention are shown.

FIG. 1 is a first cross-sectional view of a safety needle device according to one embodiment of the present invention;

FIG. 2 is a second cross-sectional view of the safety needle device in accordance with an embodiment of the present invention;

FIG. 3 is a cross-sectional view of the safety stylus of FIGS. 1 and 2 during a first stage of injection;

FIG. 4 is a cross-sectional view of the safety stylus of FIGS. 1 and 2 during a second stage of injection;

FIG. 5 is a cross-sectional view of the safety stylus of FIGS. 1 and 2 during a third stage of injection;

FIG. 6 is a cross-sectional view of the safety stylus of FIGS. 1 and 2 in a locked configuration;

fig. 7 is a cross-sectional view of the safety stylus of fig. 1 and 2 in a locked configuration.

Detailed Description

Referring to fig. 1 to 7, the safety needle device is generally designated by the numeral 1. The safety needle device can be associated with a container containing a substance to be injected into a patient or containing blood drawn by the patient.

The safety needle device 1 includes a hub 10 configured to be connected to a container and a needle 20 connected to the hub 10. The needle 20 extends along a longitudinal axis X-X between a distal end 21, formed for insertion into the patient, and an opposite proximal end 22, formed for connection to the container.

The safety needle device 1 comprises a protective shield 30, the protective shield 30 being slidable along a longitudinal axis X-X through an intermediate position relative to the needle hub 10 between an initial position before injection to a locked position after injection. Specifically, during injection of the needle into a patient, protective shield 30 slidingly passes from an initial position to an intermediate position along longitudinal axis X-X towards proximal end 22 of needle 10. Conversely, during withdrawal of the needle from the patient, the protective shield 30 is slidingly passed from the intermediate position to the locking position along the longitudinal axis X-X towards the distal end 21 of the needle 10.

According to a preferred embodiment, the protective shield 30 is configured to cover and protect the distal end 21 of the needle both in the initial position and in the locked position. In particular, the boot 30 is configured to be locked in a locked position to avoid further sliding to expose the distal end 21 of the needle after injection.

Preferably, the protective cover 30 is rotationally constrained about the longitudinal axis X-X.

More preferably, the protective cover 30 comprises a tubular body 33 extending along the longitudinal axis X-X, the tubular body 33 defining a passage channel 34 through which at least part of the needle hub 10 is inserted.

It will be noted that the protective cover 30 has an inner surface 31 facing inwardly towards the needle hub 10 and an opposite outer surface 32 facing outwardly. In particular, the tubular body 33 has an inner surface 31 facing the through passage 34.

According to one embodiment, shield 30 has indicia 36 on outer surface 32, the indicia 36 configured to indicate a use status of the safety needle device. In particular, the logo 36 is formed such that the logo 36 is visible when the boot 30 passes from the initial position to the locked position.

The safety needle device 1 includes a housing 40, the housing 40 being attached to the needle hub 10 and surrounding a portion of the needle hub 10, the housing 40 surrounding a portion of the protective cover 30 when the protective cover 30 is in the initial position and the locked position; the housing 40 surrounds substantially all of the protective cover 30, preferably all of the protective cover 30, when the protective cover 30 is in the intermediate position. Preferably, the housing 40 includes a tubular body 43 having a through passage 44. In particular, in the initial position, the protective cover 30 is at least partially inserted into the passage channel; and in the intermediate position the protective cap 30 is inserted almost entirely, preferably entirely, into the through passage. In detail, the protective cover 30 comprises a first length portion inserted in the initial position through the passage and a second length portion inserted in the locked position through the passage, wherein the first portion is equal to or longer than the second portion. Boot 30 further includes a third length portion inserted through the channel at an intermediate position, wherein the third portion is longer than the first length portion and the second length portion. Preferably, the third length portion is equal to the length of the boot 30.

Preferably, housing 40 has an inner surface 41 facing at least a portion of protective cover 30 and an opposite outer surface 42 facing outwardly. More preferably, the inner surface 41 of the housing 40 partially faces the outer surface 33 of the protective cover 30. It is to be noted that the tubular body 43 has an inner surface 41 of the housing 40 facing the through passage 44 of the housing.

The safety needle device 1 comprises a guiding arrangement 80, which guiding arrangement 80 is configured to guide the protective shield 30 along the longitudinal axis X-X between an initial position and a locked position to prevent relative rotation of the protective shield 30 with respect to the housing 40 and the needle hub 10. Specifically, the guide arrangement 80 includes a first guide member 81 formed on the protective cover 30 and a second guide member 82 formed on the housing 40. In detail, the first guide member 81 is configured to cooperate with the second guide member 82 to guide the sliding of the protection shield 30 along the longitudinal axis X-X and to prevent the rotation of the protection shield 30 with respect to the casing 40.

Preferably, the first guide member 81 is formed on the outer surface 32 of the protective cover 30, and the second guide member 82 is formed on the inner surface 41 of the housing 40.

More preferably, the second guide member 82 includes a longitudinal groove 83 formed on the inner surface 41 of the housing 40. In particular, the longitudinal groove 83 is rectilinear and extends along the longitudinal axis X-X. Alternatively, the first guide member 81 includes a tab 84 protruding from the outer surface 32 of the boot 30 and configured to engage the longitudinal slot 83. This engagement is maintained from the initial position and the locked position of boot 30.

Even more preferably, the first guide members 81 are angularly spaced on the outer surface 32 of the protective cover 30 and the second guide members 82 are angularly spaced on the inner surface 41 of the housing 40.

Safety needle device 1 includes a resilient member 50 disposed within the housing and acting on protective shield 30. Preferably, the resilient member 50 is configured to urge the shield 30 all the way towards the distal end 21 of the needle 10. Specifically, resilient member 50 is biased to urge shield 30 towards distal end 21 of needle 10, in contrast to longitudinal sliding of shield 30 towards the proximal end of needle 10. In detail, the elastic member 50 is configured to be elastically compressed as the shield 30 passes from the initial position to the intermediate position during injection, and is configured to be elastically extended as the shield 30 passes from the intermediate position to the locking position during withdrawal.

Preferably, the elastic member 50 is interposed between the needle holder 10 and the protection cover 30 so as to continuously push the protection cover 30. Specifically, the needle hub 10 includes a stop wall 11 configured to receive a portion of the resilient member 50. Alternatively, the protective cover 30 comprises an annular flange 35, the annular flange 35 protruding from the inner surface 31 of the protective cover 30 and configured to retain the distal portion 51 of the resilient member 50.

More preferably, the elastic member 50 extends along the longitudinal axis X-X between the distal portion 51 and the proximal portion 52. Thus, the stop wall 11 receives the proximal portion 52 of the resilient member 50 and the annular flange 35 receives the distal portion 51 of the resilient member 50.

Safety needle device 1 comprises a sleeve 60 arranged within housing 40 and rotatably mounted with respect to shield 30 and housing 40 about a longitudinal axis X-X. Specifically, the sleeve 60 surrounds at least a portion of the needle hub 10 and is configured to rotate relative to the needle hub 10 about the longitudinal axis X-X.

Specifically, the sleeve 60 has an inner surface 61 facing the needle hub 10 and an opposite outer surface 62 facing outwardly at least partially the inner surface 41 of the housing 40.

According to an embodiment, boot 30 surrounds at least part of sleeve 60 when boot 30 is in the initial position and in the locked position. However, when the boot 30 is in the intermediate position, the boot 30 surrounds the sleeve 60 almost entirely, preferably entirely. In detail, when the protective cover 30 is in the initial position and the locked position, the sleeve 60 is at least partially inserted into the through passage 34 of the protective cover 30. In contrast, when the protective cap 30 is in the intermediate position, the sleeve 60 is inserted almost entirely, preferably entirely, into the through-passage 34 of the protective cap 30. In more detail, the first length portion and the second length portion of the protective cover 30 at least partially surround the sleeve 60 in the initial position and the locked position, respectively. In contrast, the third length of the protective cap 30 in each case surrounds the sleeve 60 in the intermediate position almost completely, preferably completely.

It should be noted that the inner surface 41 of the housing 40 faces at least part of the sleeve 60 and the protective cover 30. Furthermore, the inner surface 31 of the boot 30 partially faces the sleeve 60 and the outer surface 32 of the boot 30 partially faces the inner surface 41 of the housing 40. Thus, the inner surface 61 of the sleeve 60 faces partly the needle hub 10 and the opposite outer surface 62 faces partly the inner surface 31 of the protective cover 30 and the inner surface 41 of the housing 40.

Advantageously, the relationship between the inner surfaces 31, 41, 61 and the outer surfaces 32, 42, 62 is maintained in the initial, intermediate and locked positions of the protective cover 30.

According to a preferred embodiment, the elastic member 50 surrounds at least part of the sleeve 60. Specifically, the resilient member 50 surrounds the outer surface 62 of the sleeve 60.

The safety needle device 1 comprises a locking arrangement 70, which locking arrangement 70 is configured to rotate the sleeve 60 and lock the protective shield 30 in a locked position when the protective shield 30 is slid. In particular, the locking arrangement 70 comprises at least one first locking member 71 formed on the protective cover 30 and at least one second locking member 72 formed on the sleeve 60. In detail, the first locking member 71 cooperating with the second locking member 72 is configured to rotate the sleeve when the protective cover 30 slides, and lock the protective cover 30 in the locked position. Preferably, the first locking member 71 cooperating with the second locking member 72 is configured to rotate the sleeve during sliding of the protective cover 30 and to lock the protective cover 30 in the locked position.

In more detail, the first locking member 71 cooperates with the second locking member 72 to guide the protective cover 30 from the initial position to the locking position through the intermediate position. Further, when the boot 30 itself reaches the lock position, the first lock member 71 and the second lock member 72 cooperate to lock the boot 30 in the lock position.

Preferably, the first locking member 71 is formed on the inner surface 31 of the protective cover 30, and the second locking member 72 is formed on the outer surface 62 of the sleeve 60.

According to an embodiment, the second locking member 72 comprises a slit (slit)73 and the first locking member 71 comprises a pin 74 configured to engage with the slit 73.

Preferably, the slit 73 includes a first stopper section 73a, a second stopper section 73b, and a locking section 73c configured to longitudinally limit sliding of the protection cover 30.

Specifically, the first stop segment 73a is configured to engage the pin 74 in an initial position of the protective shield 30 to prevent the protective shield 30 from sliding longitudinally toward the distal end 21 of the needle 20. Conversely, second stop segment 73b is configured to engage pin 74 at an intermediate position of protective shield 30 to prevent longitudinal sliding of protective shield 30 toward proximal end 22 of needle 20. It should be noted that first stop segment 73a and second stop segment 73b are configured to limit the travel of boot 30 along the longitudinal axis. In effect, first stop segment 73a holds boot 30 against the pre-loaded spring force of resilient member 50, which urges boot 30 towards distal end 21, while second stop segment 73b is configured to stop boot 30 in an intermediate position during injection.

The locking section 73c is configured to engage the pin 74 in the locked position of the protective shield 30 to prevent longitudinal sliding of the protective shield towards both the distal end 21 and the proximal end 22 of the needle 10. In particular, locking section 73c is configured to retain pin 74 so as to prevent further use of safety needle device 1 and sliding of the protective shield in the longitudinal direction. Preferably, locking segment 73c also limits the travel of boot 30 along longitudinal axis X-X, thereby retaining boot 30 against the pre-loaded spring force of resilient member 50, which also continues to force boot 30 toward distal end 21 in the locked position. More preferably, the locking segment 73C has a "C" shape configured to receive and retain the pin 74, preventing further sliding of the boot 30 when the pin 74 reaches the locking segment 73C.

According to an embodiment, the slit 73 further comprises a first rotational section 73d and a second rotational section 73e, the first rotational section 73d and the second rotational section 73e being configured to convert a longitudinal sliding of the protective cover 30 into a rotation of the sleeve 60. Specifically, the first and second rotating segments 73d and 73e engage with the pin 74 to rotate the sleeve 60.

In detail, the first rotation section 73d is configured to engage the pin 74 and rotate the sleeve 60 when the protective cover 30 slides along the longitudinal axis X-X from the initial position towards the intermediate position. Alternatively, the second rotational segment 73e is configured to engage the pin 74 and rotate the sleeve 60 as the boot 30 slides along the longitudinal axis X-X from the neutral position toward the locked position. In other words, the first rotation section 73d provides a first rotation of the sleeve 60 about the longitudinal axis X-X during injection, while the second rotation section 73e provides a second rotation of the sleeve 60 about the longitudinal axis X-X during withdrawal.

Preferably, rotation of sleeve 60 allows passage of a pin from first stop segment 73a to locking segment 73c (passage) to longitudinally lock boot 30.

More preferably, the slit 73 further comprises a guiding segment 73f, which guiding segment 73f is configured to slide along at least a portion of the longitudinal axis X-X for the boot, engaging the pin 74 and avoiding the sleeve 60 from rotating. Specifically, during injection, after a first rotation of the sleeve, the pin 74 engages with the guide section 73f until the second stop section 73b reaches an intermediate position of the protective cap 30. Subsequently, during extraction, the pin 74 engages with the guide section 73f until it reaches the second rotation section 73e allowing the second rotation of the sleeve 60.