阅读说明：本技术 用于操控器械的器械盒 (Instrument box for operating instrument ) 是由 K·莱赫托宁 G·沃尔蒂 于 2018-07-05 设计创作，主要内容包括：本发明公开了一种用于操控器械(111)的器械盒(100),所述器械盒包括：用于机械地支撑器械(111)的支撑结构(101)；和遮蔽结构(102,103),所述遮蔽结构用于容纳所述器械(111)的操作部分(112),使得降低意外地接触所述操作部分(112)的风险。所述遮蔽结构(103)的至少一个壁(104)包括用于允许液态和气态物质流过所述壁的通道(105)。所述物质可以包括例如在高压灭菌消毒处理中使用的热蒸汽。通道(105)被成形为防止所述器械(111)的操作部分(112)经由所述通道(105)穿过壁(104)突伸出。因此,不需要大量的难以以有成本效益的方式制造的非常小的通道。(The invention discloses an instrument box (100) for manipulating an instrument (111), comprising: a support structure (101) for mechanically supporting an instrument (111); and a shielding structure (102, 103) for accommodating an operating portion (112) of the instrument (111) such that the risk of accidentally contacting the operating portion (112) is reduced. At least one wall (104) of the shielding structure (103) comprises a passage (105) for allowing liquid and gaseous substances to flow through the wall. The substance may include, for example, hot steam used in an autoclave sterilization process. The channel (105) is shaped to prevent an operative portion (112) of the instrument (111) from protruding through the wall (104) via the channel (105). Thus, a large number of very small channels, which are difficult to manufacture in a cost-effective manner, are not required.)

1. A cartridge (100) for manipulating an instrument, the cartridge comprising:

-a support structure (101) for mechanically supporting the instrument; and

-at least one shielding structure (102, 103) for accommodating and reducing the risk of accidental contact with an operating portion of the instrument,

wherein at least one wall (104) of the shielding structure comprises a channel (105) for allowing liquid and gaseous substances to flow through the wall, characterized in that the channel is shaped such that a straight, non-curved round rod with a diameter (D1) greater than 1.5mm cannot penetrate the wall via the channel when it is perpendicular to a geometrical plane parallel to the wall, in order to prevent the operative portion of the instrument from protruding through the wall via the channel, and a curved round rod with a diameter (D2) greater than 1.5mm can penetrate the wall via the channel, in order to provide a cross-sectional flow area for the liquid and gaseous substances.

2. An instrument cartridge according to claim 1, wherein the channel is inclined relative to a geometric line perpendicular to the wall such that the channel points obliquely away from the support structure to prevent the operative portion of the instrument from protruding through the wall via the channel.

3. The cartridge of claim 2, wherein the channel is inclined at an angle of at least 30 degrees and at most 70 degrees relative to the geometric line.

4. The instrument cartridge of any one of claims 1-3, wherein each of the channels has a rectangular profile when viewed along a geometric line perpendicular to the wall.

5. The instrument cartridge of any one of claims 1-4, wherein the wall comprising the channel is a bottom of the obscuring structure.

6. The instrument cartridge according to any one of claims 1-5, wherein the instrument cartridge further comprises a cover element (106, 107) covering a space for accommodating an operating portion of the instrument, thereby further reducing the risk of accidental contact with the operating portion.

7. The cartridge according to claim 6, wherein the cover element comprises a channel (108) for allowing liquid and gaseous substances to flow through the cover element.

8. The cartridge according to claim 7, wherein the passage of the cover element is shaped such that a straight, non-bent round rod with a diameter of more than 1.5mm cannot penetrate the cover element via the passage of the cover element when it is perpendicular to a geometrical plane parallel to the cover element to prevent the operative portion of the instrument from protruding through the cover element via the passage of the cover element, and a bent round rod with a diameter of more than 1.5mm can penetrate the cover element via the passage of the cover element to provide a cross-sectional flow area for liquid and gaseous substances.

9. An instrument cartridge according to claim 8, wherein the passage of the cover member is inclined relative to a geometric plane parallel to the cover member such that when the cover member covers the space for accommodating the operative portion of the instrument, the passage of the cover member is obliquely directed away from the support structure to prevent the operative portion of the instrument from protruding through the cover member via the passage of the cover member.

10. The instrument cartridge of any one of claims 1-9, wherein the material of the instrument cartridge comprises polyphenylene sulfide "PPS".

Technical Field

The present disclosure relates to a cartridge for manipulating an instrument, which may be, for example but not necessarily, a medical or dental hand-held instrument. The instrument cassette may be used to hold instruments, for example, when the instruments are sterilized by autoclaving.

Background

In many cases, instruments are handled by means of instrument cassettes, each of which is adapted to hold an instrument set during, for example, an autoclave sterilization process. The instruments placed in the instrument magazine may for example comprise medical and/or dental hand-held instruments required for performing the given measures. The instrument cassettes typically include a support structure for mechanically supporting the instruments so that the instruments are adjacent to each other. Furthermore, the instrument cartridge may comprise shielding structures for accommodating the operative portion of the instrument, thereby reducing the risk of accidentally touching the operative portion. Herein, the phrase "operation portion" refers to a portion of the instrument for performing an operation according to the purpose of use of the instrument. The operative portion may be a blade such as a knife. The shielding structure includes a passage for allowing liquid and gaseous substances to flow through the shielding structure and thereby contact the operative portion of the instrument. Such substances may include, for example, hot steam used in an autoclave sterilization process.

The inherent challenges associated with cartridges of the type described above are: on the one hand, the shielding structure should be sufficiently open to allow liquid and gaseous substances to flow through the shielding structure, but on the other hand, the shielding structure should be sufficiently closed to reduce the risk of accidentally touching the operating portion. Furthermore, in the case where the operative portion of the instrument is a sharp, long spike with a bend, there is a risk that the operative portion protrudes through the shielding structure via one of its passages. One direct way to prevent the operative portion of the instrument from protruding through the shielding structure is to make the passage sufficiently small. However, this approach results in the number of channels having to be large and thus the isthmus between the channels having to be narrow to provide sufficient flow area for liquid and gaseous substances to flow through the shielding structure. The cartridge is typically made of plastic, for example polyphenylene sulfide "PPS", and the narrow plastic isthmus can be mechanically weak and easily damaged. Another straightforward approach is to provide a sufficiently dense grid of fine wires for the passage of the shielding structure. However, this approach complicates and increases the cost of manufacturing the cartridge.

Disclosure of Invention

The following presents a simplified summary in order to provide a basic understanding of some embodiments of the invention. This summary is not an extensive overview of the invention. It is intended to neither identify key or critical elements of the invention nor delineate the scope of the invention. The following summary merely presents some concepts of the invention in a simplified form as a prelude to a more detailed description of exemplary embodiments of the invention.

In this document, the word "geometry" when used as a prefix denotes a geometrical concept, which is not necessarily part of any physical object. The geometric concept may be, for example, a geometric point, a geometric line, a geometric plane, a non-planar geometric surface, a geometric space, or any other geometric entity in zero, one, two, or three dimensions.

According to the present invention, a new cartridge for manipulating an instrument, such as a medical or dental hand-held instrument, is provided.

The instrument box comprises:

-a support structure for mechanically supporting an instrument; and

-at least one shielding structure for accommodating and reducing the risk of accidental touching of the operating portion of the instrument.

At least one wall of the shielding structure comprises channels for allowing liquid and gaseous substances to flow through the wall, such as hot steam used in an autoclave sterilization process. The wall may for example be the bottom of the shielding structure. The channel is shaped such that a straight, non-curved round rod with a diameter larger than 1.5mm cannot penetrate the wall via said channel when it is perpendicular to a geometrical plane parallel to the wall, in order to prevent the operative portion of the instrument from protruding through the wall via the channel, and such that a bendable round rod with a diameter larger than 1.5mm can penetrate the wall via the channel, in order to provide a sufficient cross-sectional flow area for liquid and gaseous substances. The channel may, for example, but not necessarily, be inclined with respect to a geometric plane parallel to the wall, such that the channel points obliquely away from the support structure to prevent the operative portion of the instrument from protruding through the wall via the channel. Thus, because the channels are shaped in the manner described above, a large number of small channels or a dense grid of fine wires over the channels is not required.

Numerous exemplary and non-limiting embodiments are described in the appended dependent claims.

Various exemplary and non-limiting embodiments as to construction and methods of operation, together with additional objects and advantages thereof, will be best understood from the following description of specific exemplary and non-limiting embodiments when read in connection with the accompanying drawings.

The verbs "comprise" and "comprise" are used in this document as open-ended limitations that neither exclude nor require the presence of unrecited features. The features recited in the dependent claims may be freely combined with each other, unless explicitly stated otherwise. Furthermore, it should be understood that the use of "a" or "an" (i.e., singular forms) throughout the document does not exclude a plurality.

Drawings

Exemplary and non-limiting embodiments and advantages thereof are described in more detail below, by way of example, with reference to the accompanying drawings, in which:

FIGS. 1a and 1b illustrate an instrument cartridge according to an exemplary and non-limiting embodiment;

FIGS. 1c and 1d show details of an instrument cartridge according to an exemplary and non-limiting embodiment; and

fig. 2 shows details of an instrument cartridge according to an exemplary and non-limiting embodiment.

Detailed Description

The specific examples provided in the following description should not be construed as limiting the scope and/or applicability of the appended claims. The list and set of examples provided in the description are not exhaustive unless explicitly stated otherwise.

Fig. 1a and 1b show an instrument cartridge 100 according to an exemplary and non-limiting embodiment. Fig. 1a shows an isometric view of the instrument cartridge 100, while fig. 1b shows a cross-sectional view taken along the line a-a shown in fig. 1 a. The cross-sectional plane associated with fig. 1b is parallel to the yz-plane of the coordinate system 199. The instrument cartridge 100 includes a support structure 101 for mechanically supporting an instrument, such as a medical or dental hand-held instrument. In the exemplary case shown in fig. 1a and 1b, one exemplary instrument 111 is present in the instrument cartridge 100. The cartridge 100 includes shielding structures 102 and 103 for receiving and reducing the risk of accidentally touching the operative portion of the instrument. The operation portion of each instrument is a portion of the instrument for performing an operation according to the purpose of use of the instrument. The operative portion may be, for example, a blade of a knife. The exemplary cartridge 100 includes shielding structures 102 and 103 at both ends thereof, and thus the cartridge 100 is suitable for an instrument having an operating portion at both ends. However, it is also possible that the instrument cartridge according to the exemplary embodiment comprises only one shielding structure and is therefore suitable only for instruments having an operating portion at one end only. The material of the cartridge 100 may include, for example, polyphenylene sulfide "PPS".

The shielding structure 102 is depicted in more detail in fig. 1 b. The shielding structure 103 may be similar to the shielding structure 102. The walls 104 of the shielding structure comprise channels for allowing liquid and gaseous substances, such as hot steam used in an autoclave sterilization process, to flow through the walls 104. In fig. 1b, one of the channels is indicated with reference numeral 105. These channels are inclined with respect to a geometrical plane parallel to the wall 104, so that the channels are directed obliquely away from the support structure 101 and thus away from the instrument 111, to prevent the operating portion 112 of the instrument 111 from protruding through the wall 104 via one of the channels. Thus, because the channels are oriented in the manner described above, a large number of small channels or a dense grid of fine wires over the channels is not required. The channel is inclined so much that a straight, non-curved round rod with a diameter greater than 1.5mm cannot penetrate the wall 104 via the channel when it is perpendicular to a geometrical plane parallel to the wall 104. Thus, the operative portion of the instrument is prevented from protruding through the wall 104 via the channel. It is also possible that the channel is inclined too much, so that a geometric line perpendicular to a geometric plane parallel to the wall 104 cannot penetrate the bottom 104 through the inclined channel, i.e. a person cannot see through the channel when looking along a geometric line perpendicular to the wall 104.

In the exemplary cartridge 100, the wall 104 is a grid of mutually parallel flat bars, the transverse direction of which is inclined with respect to a geometric plane parallel to the wall 104 and which are mechanically supported by bars whose longitudinal direction is substantially perpendicular to the longitudinal direction of the flat bars fig. 1c and 1D show details of the grid in different exemplary embodiments, in the exemplary case shown in fig. 1c, the distance D1 is at most 1.5mm, so that straight and non-curved round bars with a diameter of more than 1.5mm cannot penetrate the wall 104 via the channel 105 when they are perpendicular to the wall 104, in the exemplary case shown in fig. 1c, each channel has a rectangular profile when viewed along a geometric line perpendicular to the wall comprising the channel, in the exemplary case shown in fig. 1D, the flat bars are arranged such that one cannot see through the channel along a geometric line parallel to the z-axis of the coordinate system 199, the channel is configured with respect to the z-axis of the coordinate system (i.e. with respect to the geometric line perpendicular to the wall comprising the channel) such that the channel can be inclined with respect to the z-axis of the coordinate system 199, and the channel can be configured with a cross-section of a distance of a liquid substance, such as 30.5 mm, or 40 mm, 30 to a non-5 mm, thus providing a non-penetration of a high-pressure-capable of a fluid substance, such as a fluid substance, as a fluid substance-capable of flowing through channel, such as a fluid substance-capable of flowing through-.

In the exemplary cartridge 100, the wall 104 including the above-described channel is the bottom of the shielding structure 102. However, it is also possible that one or more side walls of the shielding structure 102 comprise a channel of the type described above.

The exemplary instrument cartridge 100 also includes cover members 106 and 107 that cover the space for receiving the operative portion of the instrument, thereby further reducing the risk of inadvertently touching the operative portion. The cover elements 106 and 107 comprise channels for allowing liquid and gaseous substances to flow through the cover elements. The passage of the cover member may be similar to the passage of the wall 104. In fig. 1b, one of the channels of the cover element 106 is indicated with reference numeral 108. As shown in fig. 1b, the passage of the cover element 106 is inclined with respect to a geometrical plane parallel to the cover element, such that when the cover element covers the space for accommodating the operative portion of the instrument, the passage of the cover element is obliquely directed away from the support structure 101 to prevent the operative portion of the instrument from protruding through the cover element via the passage of the cover element. In the exemplary cartridge 100, the cover members 107 and 108 are hinged to the body section of the cartridge 100. However, it is also possible, according to an exemplary embodiment, for the one or more cover elements to be form-locked with or otherwise mechanically connected to the body section of the cartridge. It is also possible that the cartridge according to an exemplary embodiment does not comprise any cover element of the above-described type.

The specific examples provided in the description given above should not be construed as limiting the scope and/or applicability of the appended claims. The lists and groups of examples provided in the description given above are not exhaustive unless explicitly stated otherwise.