BR202019026790Y1 - IMPROVEMENT ON DISPOSABLE SELF-LOCKING CRANIAL DRILLING DRILL - Google Patents

Abstract

IMPROVEMENT IN A DISPOSABLE SELF-LOCKING CRANIAL DRILL DRILL, this is a drill belonging to the medical devices sector, with the objective of reducing manufacturing costs and the ability to perform cuts capable of reaching bones of great thickness. It consists of a primary drill (1), secondary drill (2) called limiter, limiter ring (3), trigger (4), spring (5), retaining ring (6) and Hudson coupling body (7), having the drag geometry by opposing cams, formed by the interaction between the flat face (14) and helical ramp (15) of the primary drill (1) and the drag profile formed by (34 and 35) of the limiter ring (3), as well as the interaction between the housing (42 and 43) of the trigger (4), where the faces of the cams (14) of the primary drill (1) make contact for engaging and disengaging the assembly during drilling, smoothing the slide between the parts, and finally make the engagement and disengagement of parts smooth and precise. The conjunction between the rake angle profiles (106 and 203) of the primary drill (1) and limiter (2), in combination with the facet (105), applied to the clearance angle on the primary drill (1), in addition to the recess (25) of the limiter (2), allow the chips to easily exit the bone, the aforementioned sharpening geometry also prevents the drill from blocking before (...).

Description

APPLICATION FIELD

[1] This Utility Model Patent descriptive report deals with a drill belonging to the medical devices sector, with the objective of reducing manufacturing costs and the ability to perform cuts capable of reaching bones of great thickness.

[2] The Utility Model Patent, now in question, is an improvement on BR 20 2014 004497-9 of the same holder.

DESCRIPTION OF THE STATE OF THE TECHNIQUE

[3] Cranial surgical procedures generally require access to brain structures. To do this, it is necessary to drill holes through the cranial bone to gain access to the areas of interest to the neurosurgeon.

[4] The techniques used in skull drilling are similar to those used in carpentry, such as the pua bow, for example. Furthermore, there is a need to preserve the lower layers, such as the meninges or the brain itself, so that they are not damaged.

[5] There are cranial drills that allow the drill to rotate only when the drill is subjected to an axial load of the desired magnitude. Once the load is removed or falls below a predetermined limit, rotation of the drill ceases.

[6] Such devices utilizing an engagement mechanism that allows a driver to be engaged only with sufficient axial load are disclosed in U.S. Patents 2,842,131; 4,362,161; 4,319,577; 4,884,571; and 4,699,550 and EP 2022414 A1.

[7] Previous patents describe reusable punches that allow disassembly and assembly for cleaning and sterilization processes. Furthermore, there is a risk of the drill being assembled incorrectly and consequently failing during surgery, causing injury or death to the patient. Then, disposable drills were developed that started to adopt a body made of plastic to keep the mechanism protected and preventing or hindering its disassembly, as disclosed in U.S. Patents 4,699,550; 4,456,010; 4,830,001; 5,380,333.

[8] Another disadvantage seen in cranial drills would be the greater number of components or complex geometries, which require more expensive processes that increase the final cost of the product. And finally, the cutting areas seen in other drills are not capable of reaching thick bones.

TECHNICAL DIFFERENCE

[9] After several studies and research, the DISPOSABLE SELF-LOCKABLE CRANIAL DRILL DRILL IMPROVEMENT was developed in an intelligent and unusual way, which refers to a primary drill consisting of a shaft with two diameters, with the larger diameter presenting the cutting profile at one end and two integrated cams at the other, and the smaller diameter serves as a guide for the engagement and disengagement mechanism; a secondary drill, called “limiter”, mounted with a threaded ring that interacts with the cams of the primary drill; a bushing called “trigger”, which is responsible for transmitting the rotary movement during drilling; a retaining ring fixed to the smaller diameter of the primary drill shaft that maintains trigger travel; a helical spring, auxiliary to disengage the drill; a body with plastic coupling where the entire set is assembled and sterilized.

[10] The proposed approach enables a single-use process with improved safety and performance by reducing moving parts.

[11] This cranial drill bit features a release system and cutting profile that is different from those currently available, providing a unique and exclusive performance.

BRIEF DESCRIPTION OF THE DRAWINGS

[12] THE IMPROVEMENT ON A DISPOSABLE SELF-LOCKING CRANIAL DRILL DRILL and its applicability will be made known by reading the detailed description that follows and by observing the attached illustrative drawings, to which reference is made, in order to better elucidate the description, where: Figures 1 to 5 refer to the general description of the set; Figure 1 represents the isometric view of the assembled drill and 1A represents the exploded isometric view of the assembly components; Figure 2 represents the drill in section in the front view in the disengaged condition; Figure 3 represents the drill in section in the frontal view in the condition engaged on the cranial bone; Figure 4 represents the sectional view of the cam section in the engaged condition during drilling; Figures 5A and 5B represent the interaction of the cam with the limiter ring in the disengaged and engaged conditions respectively; Figures 6 to 11B refer to the detailed description of claim 1; Figure 6 represents the isometric view of the primary drill consisting of a shaft with two diameters, with the larger diameter presenting the cutting profile at one end and two integrated cams at the other, and the smaller diameter serving as a guide for the trigger hole. so that it couples to the cam and transmits the rotary movement; Figure 7 represents the exploded view of the secondary drill, called “limiter”, where the ring is threaded; Figure 8 represents the isometric view of the limiter ring and the shoulders, which interact with the primary drill cam; Figure 9 represents the isometric view of the limiter assembly with the ring, forming a subassembly that interacts with the primary drill cams; Figure 10 represents the isometric view of the trigger; Figure 11A represents the isometric sectional view of only the coupling body and the trigger, representing the assembly in the engaged condition; Figure 11B represents the isometric sectional view of only the engagement body and the trigger, representing the assembly in the disengaged condition; Figure 12 represents a sectional view of the body of the Hudson type hitch. Figures 13 to 18 refer to the detailed description of claim 2; Figure 13 is the bottom view of the primary and secondary drill showing the sharpening arrangement; Figure 14 is the front view of the primary and secondary drill sharpening; Figure 15 is the bottom view of the primary drill sharpening; Figure 16 is the front view of the primary drill sharpening; Figure 17 is the bottom view of the secondary drill sharpening; Figure 18 is the front view of the secondary drill sharpening.

DETAILED UTILITY MODEL DESCRIPTION

[13] According to Figure 1, we have the complete assembly of the present patent application, and Figure 1A shows the explosion of the constituent parts of said assembly, which include the primary drill (1), the secondary drill (2) called limiter , the limiter ring (3), the trigger (4), the spring (5), the retaining ring (6) and finally the Hudson hitch body (7). The assembly is shown under two operating conditions.

[14] In Figure 2 we have a sectional view of the drill assembly in rest condition, that is, in the disengaged condition, where the primary drill cams (1) remain disengaged from the trigger (4) through spring pressure (5 ) and the retaining ring (6), which limits the travel between the primary drill (1) and the trigger (4). The primary drill (1) and limiter (2) are mounted so that the cutting geometries of both remain aligned with the cam faces through the limiter ring (3), as shown in the Figure 4 section.

[15] This interaction allows that, when connecting the drill to a craniotome through the body of the Hudson coupling (7), and pressing on the cranial bone, as shown in Figure 3, the cams of the primary drill (1) are engaged in the housing of the trigger (4). The travel of the engagement is limited between the contact of the lower face of the trigger (4) and the upper face of the limiter ring (3). Once engagement has occurred, the transmission of the rotary movement of the craniotome is carried out.

[16] Upon reaching the bone thickness, the primary drill (1) is disengaged from the trigger (4), assisted by the spring load (5). The primary mouth cams (1) also slide so that the upper face of the larger diameter of the primary drill (1) remains coincident with the upper face of the limiter ring (3) with a small axial clearance of approximately 0.4 mm between the trigger (4) and the limiter ring (3). In this way, the primary drill (1), limiter (2) and limiter ring (3) remain stationary in the bone, while the other components continue to rotate in error. This condition is shown in Figure 5A and Figure 5B shows the position of the primary drill cams (1) when the assembly is pressed and the cams are engaged.

[17] The result obtained is a hole with two diameters, one hole corresponding to the diameter (10) of the primary drill (1), which starts between the surface formed by the limiter (3) and in the final portion of this hole a small bone disc, in order to help protect the dura mater (known as a “bone pad”); and a second recessed hole between the surface of the bone, up to a distance that can vary between 1 and 3 mm before the end of the first hole, corresponding to the diameter (21) of the limiter (2).

[18] Returning to Figure 1A, to the individual parts of the drill that will be described in more detail. The primary drill (1), shown in Figure 6, consists of a shaft with two diameters (10 and 11), with the larger diameter (10) having the cutting profile (16) at one end, which will be described further. forward, and two cams opposite each other at the other end.

[19] Each of the cams is made up of two faces. A flat face (14) makes contact with the face (34) of the limiter ring, shown in Figures (7, 8 and 9). This contact guarantees the alignment of the cutting geometries (16 and 24), shown in Figure 5, and allows the dragging of the rotary movement between the primary drill (1) and the limiter (2).

[20] A portion of the face (14 and 15) is exposed by approximately 1.2 mm and makes contact with the face (42) of the trigger, shown in Figures (10, 11A and 11B), being responsible for transmitting the rotary movement of the trigger. craniotome for the primary drill and for the limiter (2).

[21] The other face of the cam (15) starts as a flat base, and continues from the center with a helical rising ramp of 36mm pitch to the face (17). This surface (15) makes contact with the face (35) of the limiter ring, shown in Figures (7, 8 and 9) during drilling. When the thickness of the bone is overcome, drag occurs between them, allowing decoupling, as shown in Figures 11A and 11B. The larger diameter (10) serves as a guide for the hole (26) of part 2, shown in Figure 7.

[22] The smaller diameter (11) serves as a guide for the trigger hole (41), shown in Figure 10. At the upper end of part 1 we have a channel (12), where the retention ring (6) is mounted. This ring limits the travel between the trigger (4) and the limiter ring (3) during engagement and disengagement of the drill, shown in Figures 11A and 11B, and more specifically the channel (12) of Figure 6, the face (36 ) of the limiter ring in Figure 8 and the faces (44 and 46) of the trigger in Figure 10. On the upper face of the primary drill (1) there is a hole (13) that serves as a housing for the spring (5).

[23] The secondary drill, called limiter (2), is assembled with the limiter ring (3), forming a subassembly, as shown in Figures 7, 8 and 9. The limiter has a hole (26), where it is mounted the primary drill (1), a thread (22) at the upper end, which the thread of the limiter ring (32) is mounted, a flat face (23) for seating the limiter ring on the face (31).

[24] Fixing the ring can be carried out with the help of a wrench fixed to the faces (33) with a torque of 15Nm. At the other end, we have the cutting profile (24), which will be described below, and a diameter (21), which includes a recess (25) whose function is to reduce lateral friction during drilling of thicker bones. As shown previously, the cam drag profile is formed by (34 and 35) Figure 8 and interacts with the cams (14 and 15), shown in Figure 6 and also interacts with (42) Figure 10 in the engagement and disengagement mechanism of the drill, shown in Figures 11A and 11B.

[25] The trigger (4) is a metallic sleeve, made of bronze, formed by the hole (41) Figure 10 with sliding adjustment between this and the diameter (11) of the primary drill (1) Figure 6. It has a housing (42 and 43) where the faces of the cams (14) of the primary drill (1) make contact for engaging and disengaging the assembly during drilling. The lower face (44) remains in contact with the upper face (36) of the limiter ring when engaged during drilling. In the disengaged condition, the face (46) remains in contact with the retaining ring (6). It has a thread (45), which is mounted on the thread (74) on the Hudson hitch body (7) Figures 10 and 12.

[26] The entire drill engagement and disengagement mechanism of the present invention is encapsulated in the plastic Hudson coupling body (7). It has a body (71), where the coupling is mounted on the craniotome, and the coupling model can vary according to the craniotome from other manufacturers, such as the Smith type coupling, for example. The diameter (72) serves to cover the limiter ring (3), the upper part of the limiter (2) and the two cams formed by (14, 15 and 17) Figure 6. The spring (5), mounted in the housing ( 13) of part 1 Figure 1 is also supported in the housing (73) of the coupling body Figure 12, so that it can have sufficient load to assist in disengaging the drill cams, shown in Figures 11A and 11B. As previously mentioned, the thread (75) is assembled with the thread (45) of the trigger (4) and its seating in the Hudson coupling (7) is the contact between the faces (47 and 74) Figures 10 and 12.

[27] As previously described, the primary drill (1), shown in Figure 6, consists of a shaft with two diameters (10 and 11), with the larger diameter (10) presenting the cutting profile (16) in a end, as shown in Figure 7, the cutting profile (24) of the limiter (2).

[28] It was also described that the interaction between the faces (34 and 35) of the limiter ring (3) guarantees the alignment of the cutting geometries (16 and 24), shown in Figure 5, and allows the dragging of the rotary movement between the primary drill (1) and the limiter (2). For a better understanding of the present patent application, Figures 13 and 14 show the assembly in the engaged condition between the primary drill (1), the limiter (2) and the limiter ring (3) where the alignments of the angles of output formed by (106 and 203).

[29] There is also a distance between the edge of the tip angle (102) and the tip angle (201) that can vary between approximately 1 and 3 mm. The desired alignment and positioning are obtained by the fact that the sharpening process is carried out with the assembly assembled. Figures 15, 16, 17 and 18 show the bottom and front views of the primary drill (1) and the limiter (2).

[30] Starting with the primary drill (1), formed by the body (10), whose cut results in the smaller diameter of the hole. As shown in Figures 16 and 17, the primary drill consists of a 0.4mm tip (101), which allows the drill to remain positioned to make the hole.

[31] The cutting geometry is formed by the tip angle (102-A) of approximately 7° from the base, between the tip edge (101) to the face (10), a clearance angle (102-B) of approximately 20° from the base.

[32] Starting from the tip (101), we have a facet (103) whose angle is negative at approximately 15° in relation to the drill axis. The edge formed between the intersection of the angles (102-A, 102-B and 103) has a rounding 104 in order to smooth the cut of the primary drill (1) Figures 15 and 16, and the formation of the bone disc known as “ bone pad”.

[33] There is also a second faceted corner (105) perpendicular to the facet (103) and at an angle of approximately 40° from the axis, which reduces the contact area of the clearance angle (102-B), favoring chip egress , Figure 16.

[34] In terms of chip exit, it also includes the geometry of the exit angle (106 and 206), with an inclination of approximately 6° in relation to the axis of the primary drill (1) Figures 14, 16 and 18. As shown in Figures 13 and 15, the profile of the exit angle faces (106 and 203) form an angle of approximately 75°.

[35] This profile describes an arc path (16), shown in Figure 6, starting from the tip (101) of the primary drill (1) and ending up to the face of the recess (25) of the limiter (2) at a distance vertical of approximately 20mm, Figures 14, 16 and 18.

[36] As shown in Figure 13, the sharp faces are arranged at 120° to each other, forming the tip profile (101) and a minimum web diameter of approximately 4mm on the primary drill (1).

[37] The result of this arrangement is a greater volume for chip exit, which allows bones with greater thickness to be reached.

[38] The body of the limiter (2) is formed by two diameters (21 and 25), Figure 18. The diameter (21), whose cut results in the diameter of the recessed hole, has a recess (25) Figure 18, whose function is the reduction of lateral friction during drilling of thicker bones. As shown in Figures 17 and 18, the geometry is formed by the tip angle (201) of approximately 15° from the base, between the internal diameter (26) and the external diameter (21), a clearance angle (202) of approximately 20°, parallel with the clearance angle (102-B) of the primary drill (1) Figure 14.

[39] As previously described, the rake angle (203) is formed in conjunction with the rake angle (106) Figures 13 and 14 so that, during drilling, the surfaces formed by (106) on the primary drill (1 and 203) in limiter (2) remain coincident.

[40] According to these figures and their details presented above, the DISPOSABLE SELF-LOCKING CRANIAL DRILLING DRILL IMPROVEMENT consists of a primary drill (1), secondary drill (2) called limiter, limiter ring (3), trigger ( 4), spring (5), retaining ring (6) and Hudson coupling body (7), characterized by the fact that the opposing cam drag geometry is formed by the interaction between the flat face (14) and the helical ramp (15) of the primary drill (1) and the drag profile formed by (34 and 35) of the limiter ring (3), as well as the interaction between the housing (42 and 43) of the trigger (4), where the cam faces (14) of the primary drill (1) make contact to engage and disengage the assembly during drilling, smoothing the slip between the parts, and finally making the engagement and disengagement of the parts smooth and precise.

[41] The conjunction between the rake angle profiles (106 and 203) of the primary drill (1) and limiter (2), in combination with the facet (105), applied to the clearance angle on the primary drill (1), in addition to the recess (25) of the limiter (2), they allow easy removal of chips from the bone. The aforementioned sharpening geometry also prevents the drill from blocking before reaching the desired point, in addition to allowing drilling even in very thick bones.

[42] This is, therefore, an IMPROVEMENT ON A DISPOSABLE SELF-LOCKABLE CRANIAL DRILL DRILL, fully satisfying the proposed objectives and fulfilling the intended functions in a practical and efficient manner, providing a series of advantages inherent to its applicability, having characteristics own, innovative and equipped with fundamental novelty requirements, required to deserve Utility Model Patent protection.

Claims (1)

1) “IMPROVEMENT IN DISPOSABLE SELF-LOCKING CRANIAL DRILLING DRILL”, consisting of primary drill (1), secondary drill (2) called limiter, limiter ring (3), trigger (4), spring (5), retaining ring ( 6) and body of the Hudson coupling (7), characterized by the fact that the drag geometry by opposing cams is formed by the interaction between the flat face (14) and helical ramp (15) of the primary drill (1) and the drag profile formed by (34 and 35) of the limiter ring (3), as well as the interaction between the housing (42 and 43) of the trigger (4), where the faces of the cams (14) of the primary drill (1) make contact to engagement and disengagement of the assembly during drilling, smoothing the slip between the pieces, and finally making the engagement and disengagement of the parts smooth and precise; the conjunction between the rake angle profiles (106 and 203) of the primary drill (1) and limiter (2), in combination with the facet (105), applied to the clearance angle on the primary drill (1), in addition of the recess (25) of the limiter (2), allow the chips to exit the bone easily, the aforementioned sharpening geometry also prevents the drill from blocking before reaching the desired point, in addition to allowing drilling even in very thick bones.