KR102312312B1 - Sprocket structure for medical devices - Google Patents

Abstract

The present invention relates to a sprocket structure for a medical device, which has a damage preventing groove at an inner edge of a key way to prevent damage on edge part of the key way by preventing generation of contact resistance with a key edge when a key is inserted. Therefore, the edge part, which is a vulnerable part of the key way, is replaced with the damage preventing groove in a curved groove shape. Accordingly, when the key is inserted in the key way, the present invention prevents concentration of stress, generated at the key way, on the edge part, does not generate friction resistance between the edge part of the key and the damage preventing groove of the key, and thereby prevents a conventional problem of damage on the key way during insertion of the key into the key way.

Description

Sprocket structure for medical devices

The present invention relates to a sprocket structure for a medical device, and more particularly, by preventing contact resistance with the key edge from occurring when the key is inserted, thereby preventing the edge of the keyway from being damaged, and optimizing the width and depth of the breakage prevention groove Thus, while maintaining sufficient friction between the key and the keyway, damage to the keyway is prevented when the key is inserted, and the pressing surface is divided into two surfaces to facilitate key insertion and the key is stably supported in the keyway. is about

Medical devices such as therapeutic massagers, recycled treatment equipment, and medical beds are equipped with sprockets to transmit rotational power such as motors.

This sprocket serves to transmit the rotational power of the rotational shaft by having a rotating shaft coupled to the center and a chain connected around the sprocket.

These sprockets have radially toothed teeth so that a chain is connected to the periphery, and a coupling hole is formed in the center so that the rotating shaft is coupled.

A key groove is formed in the coupling hole of the sprocket, and a key groove is formed on the circumference of the rotation shaft coupled thereto to face the key groove of the sprocket, and a key is inserted into the key groove of the sprocket and the key groove of the rotation shaft opposite to this.

Since the key coupled to the sprocket and the rotating shaft plays an important role in transmitting the rotational power of the rotating shaft to the sprocket, the key should not flow or fall out even after long-term use.

Therefore, when the key is coupled to the keyway of the sprocket and the keyway of the rotation shaft, it is press-fitted, and when the key is inserted, it is pushed in by applying a relatively large striking force. Therefore, when the key is inserted, the edge of the key is in sliding contact with the edge of the keyway, which is a weak part of the sprocket, and there is a problem in that the edge of the keyway is damaged.

Republic of Korea Patent No. 10-1388884

An object of the present invention to solve the above problems is to provide a sprocket structure for a medical device that prevents damage to the edge of the keyway by preventing contact resistance with the edge of the key when the key is inserted.

Another object of the present invention is to provide a sprocket structure for a medical device that optimizes the width and depth of the breakage prevention groove to prevent damage to the keyway when the key is inserted while sufficiently maintaining the frictional force between the key and the keyway.

Another object of the present invention is to provide a sprocket structure for a medical device in which the pressing surface is bisected into two surfaces to facilitate insertion of the key and stably support the key in the keyway.

The sprocket structure for medical devices of the present invention for achieving the above object consists of a rotating shaft, a sprocket coupled to the rotating shaft to transmit the rotational power of the rotating shaft, and a key coupled to the rotating shaft and the sprocket so that the rotating shaft and the sprocket are fixed to each other, , In the sprocket structure for medical devices that is installed in a medical device and transmits rotational power supplied from a driving source, a key groove is formed in the coupling hole of the sprocket to which the rotation shaft is coupled, and at the inner edge of the key groove, when the key is inserted, the key edge and It is characterized in that the breakage prevention groove is formed to prevent damage to the edge of the keyway by preventing the contact resistance of the keyway from being generated.

Another feature of the sprocket structure for medical devices of the present invention is that the breakage prevention groove is formed in an arc shape, and when the width of the keyway is 3, the width of the breakage prevention groove is formed in a ratio of 0.75 to 1.05, and the depth of the keyway is In the case of 1.5, the depth of the breakage prevention groove is formed in a ratio of 0.2 to 0.35.

Another feature of the sprocket structure for medical devices of the present invention is that a pressing surface is formed in the key groove between the breakage prevention grooves so as to be in surface contact with the corresponding surface of the key, and a pressing surface dividing groove is formed on the pressing surface to bisect the pressing surface. , when the key is inserted, frictional resistance with the pressing surface is reduced to facilitate the insertion of the key, and two divided pressing surfaces are provided so as to be in surface contact with the corresponding surface of the key, respectively.

According to the present invention as described above, a breakage preventing groove is formed on the inner edge of the keyway to prevent damage to the edge of the keyway by preventing contact resistance with the key edge from occurring when the key is inserted. Therefore, since the edge portion, which is a weak part of the keyway, is replaced with a breakage prevention groove in the form of a curved groove, stress generated in the keyway is prevented from being concentrated on the edge portion when the key is inserted into the keyway, and damage to the edge portion of the key and the keyway is prevented. Frictional resistance is not generated between the grooves, and thus the conventional problem of damaging the keyway when the key is inserted into the keyway is prevented.

The breakage prevention groove of the present invention is made in an arc shape, and when the width of the keyway is 3mm, the width of the breakage prevention groove is formed in a ratio of 0.75mm to 1.05mm, and when the depth of the keyway is 1.5mm, damage is prevented The depth of the groove is formed in a ratio of 0.2mm to 0.35mm. If the width of the breakage prevention groove is less than 0.75mm or the depth of the breakage prevention groove is less than 0.2mm, the width of the breakage prevention groove is too small to reduce the stress dissipation effect, and if the width of the breakage prevention groove exceeds 1.05mm, or to prevent damage When the depth of the groove exceeds 0.35 mm, the width of the pressing surface is reduced by that much, so there is a problem in that the frictional resistance between the key and the pressing surface is greatly reduced. Therefore, when the width of the keyway is 3mm, the width of the breakage prevention groove is formed in a ratio of 0.75mm to 1.05mm, and when the depth of the keyway is 1.5mm, the depth of the breakage prevention groove is in a ratio of 0.2mm to 0.35mm It is preferable to form

And, in the key groove between the breakage prevention grooves of the present invention, a pressing surface is formed so as to be in surface contact with the corresponding surface of the key, and a pressing surface dividing groove is formed on the pressing surface to bisect the pressing surface. Accordingly, an air passage is formed in the center of the pressing surface along the insertion direction of the key by the pressing surface dividing groove, thereby facilitating the insertion of the key. In addition, since the pressing surface is divided into two by the pressing surface dividing groove, the pressing surface divided into two is in surface contact with the corresponding surface of the key, respectively. Therefore, if the pressing surface is placed on the corresponding surface of the key, the contact state is stable compared to the conventional one in which only one surface is surface-contacted.

1 is a front view showing a sprocket structure for a medical device of the present invention;
Figure 2 is a side cross-sectional view of Figure 1;
3 is a partially enlarged view of FIG. 1
4 is a schematic partial enlarged view showing a state in which the rotating shaft and the key are coupled to the coupling hole of the sprocket;
Figure 5 is a partial enlarged view showing another embodiment of the structure of the sprocket for a medical device of the present invention

Specific features and advantages of the present invention will become more apparent from the following description with reference to the accompanying drawings.

1 is a front view showing the structure of a sprocket for a medical device of the present invention, FIG. 2 is a side cross-sectional view of FIG. 1, FIG. 3 is a partially enlarged view of FIG. 1, and FIG. It is a schematic partial enlarged view showing the state.

The sprocket structure for medical devices of the present invention is coupled to the rotating shaft 10 and the sprocket 30 coupled to the rotating shaft 10 to transmit the rotational power of the rotating shaft 10, the rotating shaft 10 and the sprocket 30 The rotation shaft 10 and the sprocket 30 are made of a key 20 to be fixed to each other, and is installed in a medical device to transmit rotational power supplied from a driving source.

In the sprocket 30 of the present invention, a key groove 32 is formed in the coupling hole 31 of the sprocket 30 to which the rotation shaft 10 is coupled. In the inner edge of the keyway 32 of the sprocket 30, a breakage prevention groove to prevent damage to the edge of the keyway 32 by preventing contact resistance with the edge of the key 20 when the key 20 is inserted. (33) is formed.

As described above, since the breakage prevention groove 33 in the form of a curved groove is formed in the corner portion, which is the weak part of the key groove 32 , the stress generated in the key groove 32 when the key 20 is inserted while hitting the key groove 32 is reduced. It is prevented from being concentrated in the keyway 32 edge portion.

In addition, frictional resistance is not generated between the edge portion of the key 20 and the breakage preventing groove 33 of the key groove 32 . Accordingly, when the key 20 is inserted into the keyway 32 , the problem that the keyway 32 is damaged is prevented.

The breakage prevention groove 33 of the present invention is formed in an arc shape.

Such a breakage prevention groove 33 is made in an arc shape. When the width (H) of the keyway (32) is 3mm, the width (h) of the breakage prevention groove (33) is formed in a ratio of 0.75mm to 1.05mm, and the depth (D) of the keyway (32) is 1.5mm In this case, the depth (d) of the breakage preventing groove (33) is formed in a ratio of 0.2mm to 0.35mm.

When the width (h) of the breakage prevention groove 33 is less than 0.75mm or the depth (d) of the breakage prevention groove 33 is less than 0.2mm, the breakage prevention groove 33 formed in the corner of the keyway 32 The width h is formed too small, thereby reducing the stress dissipation effect.

When the width (h) of the breakage prevention groove 33 exceeds 1.05mm, or the depth (d) of the breakage prevention groove 33 exceeds 0.35mm, the width (W) of the pressing surface 34 of the keyway 32 ) becomes smaller. Accordingly, the frictional resistance between the key 20 and the pressing surface 34 is greatly reduced, and accordingly, there is a problem in that the coupling force between the key 20 and the keyway 32 is weakened.

Therefore, when the width (H) of the keyway (32) is 3mm, the width (h) of the breakage prevention groove (33) is formed in a ratio of 0.75mm to 1.05mm, and the depth (D) of the keyway (32) is 1.5 mm, the depth d of the breakage prevention groove 33 is preferably formed in a ratio of 0.2 mm to 0.35 mm.

The sprocket structure for medical devices of the present invention is assembled as follows.

The rotation shaft 10 is inserted into the coupling hole 31 of the sprocket 30 , and the key 20 is press-fitted into the key groove 32 of the sprocket 30 and the key groove 11 of the rotation shaft 10 .

At this time, in the inner edge of the keyway 32, when the key 20 is inserted, contact resistance with the edge of the key 20 is not generated so that the edge portion of the keyway 32 is prevented from being damaged. is formed.

Therefore, since the edge portion, which is the weak part of the keyway 32, is replaced with the breakage prevention groove 33 in the form of a curved groove, the stress generated in the keyway 32 when the key 20 is inserted into the keyway 32 is applied to the edge portion. concentration is prevented.

In addition, since frictional resistance is not generated between the edge portion of the key 20 and the breakage prevention groove 33 of the key groove 32 , the key groove 32 is damaged when the key 20 is inserted into the key groove 32 . The problem is avoided.

The breakage prevention groove 33 of the present invention is made in an arc shape, and when the width H of the keyway 32 is 3mm, the width h of the breakage prevention groove 33 is 0.75mm to 1.05mm in a ratio When the depth (D) of the keyway (32) is 1.5mm, the depth (d) of the breakage prevention groove (33) is formed in a ratio of 0.2mm to 0.35mm.

Therefore, since the width (h) and depth (d) of the breakage preventing groove 33 are optimally made, the coupling force between the key 20 and the keyway 32 is not reduced, and damage to the corner of the keyway 32 is prevented. .

5 is a partial enlarged view showing another embodiment of the sprocket structure for a medical device of the present invention.

A pressing surface 34 is formed in the key groove 32 between the breakage prevention grooves 33 so as to be in surface contact with the corresponding surface of the key 20 , and the pressing surface 34 is formed in the pressing surface 34 of the key groove 32 . ) to divide the pressing surface dividing groove 35 is formed.

Accordingly, when the key 20 is inserted, frictional resistance with the pressing surface 34 is reduced to facilitate the insertion of the key 20 , and the two divided pressing surfaces 34 are placed on the corresponding surfaces of the key 20 . Each is provided to be interviewed.

In the present invention as described above, the pressing surface dividing groove 35 is formed in the center of the pressing surface 34 along the insertion direction of the key 20, and the pressing surface dividing groove 35 is positioned at the center of the pressing surface 34 by the pressing surface dividing groove 35. Since the air passage is formed, insertion of the key 20 is facilitated.

The present invention of FIGS. 1 to 5 has the following advantages.

First, in the inner edge of the keyway 32, when the key 20 is inserted, a breakage prevention groove 33 is prevented so that contact resistance with the edge of the key 20 is not generated to prevent the edge portion of the keyway 32 from being damaged. ) is formed.

Therefore, since the corner portion, which is a weak part of the keyway 32, is replaced with the breakage prevention groove 33 in the form of a curved groove, the stress generated in the keyway 32 when the key 20 is inserted into the keyway is concentrated in the corner portion. is prevented, and frictional resistance is not generated between the edge portion of the key 20 and the breakage prevention groove 33 of the key groove 32, and accordingly, when the key 20 is inserted into the key groove 32, the key groove 32 is The conventional problem of being damaged is avoided.

Second, the breakage prevention groove 33 of the present invention is made in an arc shape, and when the width (H) of the keyway 32 is 3mm, the width (h) of the breakage prevention groove 33 is 0.75mm to 1.05mm When the depth (D) of the keyway (32) is 1.5mm, the depth (d) of the breakage prevention groove (33) is formed in a ratio of 0.2mm to 0.35mm.

When the width (h) of the breakage prevention groove 33 is less than 0.75mm or the depth (d) of the breakage prevention groove 33 is less than 0.2mm, the width h of the breakage prevention groove 33 is too small, resulting in a stress dispersing effect is lowered, and when the width (h) of the breakage prevention groove 33 exceeds 1.05mm, or the depth (d) of the breakage prevention groove 33 exceeds 0.35mm, the width (W) of the pressing surface 34 ) is smaller that much, so there is a problem in that the frictional resistance between the key 20 and the pressing surface 34 is greatly reduced.

Therefore, when the width (H) of the keyway (32) is 3mm, the width (h) of the breakage prevention groove (33) is formed in a ratio of 0.75mm to 1.05mm, and the depth (D) of the keyway (32) is 1.5 mm, the depth d of the breakage prevention groove 33 is preferably formed in a ratio of 0.2 mm to 0.35 mm.

Third, the pressing surface 34 is formed in the key groove 32 between the breakage prevention grooves 33 of the present invention so as to be in surface contact with the corresponding surface of the key 20, and the pressing surface 34 is formed on the pressing surface 34. ) to divide the pressing surface dividing groove 35 is formed.

Accordingly, an air passage is formed in the center of the pressing surface 34 along the insertion direction of the key 20 by the pressing surface dividing groove 35 to facilitate the insertion of the key 20 .

In addition, since the pressing surface 34 is divided into two by the pressing surface dividing groove 35 , the pressing surface 34 divided into two is in surface contact with the corresponding surface of the key 20 , respectively. Therefore, when the pressing surface 34 is placed on the corresponding surface of the key 20, the contact state is stable compared to the prior art in which only one surface is surface-contacted.

On the other hand, an anti-corrosion coating layer may be applied to the coupling hole 31 of the sprocket 30 to prevent corrosion of the metal surface. The coating material of this anti-corrosion coating layer is benztriazole 15% by weight, ethylene glycol butyl ether 25% by weight, hafnium 20% by weight, molybdenum emulsification (MoS ² ) 10% by weight, titanium oxide (TiO ² ) 15% by weight, phenol It is composed of 15% by weight of no-block type glycidyl ether, and the coating thickness can be formed to 8㎛.

Benztriazole, ethylene glycol butyl ether, and phenol novolac-type glycidyl ether act as corrosion protection and discoloration prevention.

Hafnium is a transition metal element with corrosion resistance, and serves to have excellent waterproof and corrosion resistance.

Molybdenum emulsified plays a role in imparting lubricity and lubricity to the surface of the coating film.

Titanium oxide is added for the purpose of fire resistance and chemical stability.

The reason why the ratio of the components and the coating thickness are numerically limited as described above is that the present inventors repeatedly failed several times and analyzed through the test results. As a result, the optimal anti-corrosion effect was exhibited at the ratio.

In addition, the antifouling coating layer made of the antifouling coating composition may be applied to the breakage prevention groove 33 to effectively prevent adhesion and removal of contaminants.

The antifouling coating composition contains mercaptobenzothiazole and amidoalkyl betaine in a molar ratio of 1:0.01 to 1:2, and the total content of mercaptobenzothiazole and amidoalkyl betaine is 1 based on the entire aqueous solution. ~10% by weight.

The mercaptobenzothiazole and amidoalkyl betaine are preferably 1:0.01 to 1:2 as a molar ratio. When the molar ratio is out of the above range, the applicability of the breakage prevention groove 33 is reduced or the surface moisture after application. There is a problem in that the coating film is removed due to an increase in adsorption.

The mercaptobenzothiazole and amidoalkyl betaine are preferably 1 to 10% by weight in the entire aqueous solution of the composition. If it exceeds, crystal precipitation due to an increase in the thickness of the coating film is likely to occur.

On the other hand, as a method of applying the present antifouling coating composition on the breakage prevention groove 33, it is preferable to apply by a spray method. In addition, the final coating film thickness on the breakage preventing groove 33 is preferably 550 ~ 2000Å, more preferably 1100 ~ 1900Å. If the thickness of the coating film is less than 550 Å, there is a problem in that it is deteriorated in the case of high-temperature heat treatment, and if it exceeds 2000 Å, there is a disadvantage that crystal precipitation on the coated surface is easy to occur.

In addition, the present antifouling coating composition may be prepared by adding 0.1 mol of mercaptobenzothiazole and 0.05 mol of amidoalkyl betaine to 1000 ml of distilled water and then stirring.

In addition, the periphery of the sprocket 30 may be coated with a fragrance material mixed with functional oil that helps to sterilize and relieve stress.

The mixing ratio of the fragrance material and the functional oil is 95 to 97% by weight of the fragrance material, and 3 to 5% by weight of the functional oil is mixed, and the functional oil is Costus oil 50% by weight, Cassie oil 50% by weight.

Here, the functional oil is preferably mixed in an amount of 3 to 5% by weight based on the fragrance material. If the mixing ratio of the functional oil is less than 3% by weight, the effect is insignificant, and if the mixing ratio of the functional oil exceeds 3 to 5% by weight, the effect is not greatly improved, while the manufacturing cost is greatly increased.

Costus oil has good effects on neuralgia, muscle pain, antidepression, and stress relief.

Cassie oil is effective in detoxifying, treating skin diseases, sterilizing, relieving itching, clearing the head, and relieving tension.

Accordingly, as the fragrance material mixed with the functional oil is coated on the sprocket 30 , effects such as sterilizing the circumference of the sprocket 30 and reducing operator fatigue can be obtained.

The reason for limiting the components and limiting the mixing ratio for the perfume material and the functional oil is the reason that the present inventor repeatedly failed several times and analyzed through the test results. As a result, the optimal effect in the composition and numerical limit ratio because it showed

10: axis of rotation 11: keyway
20: key 30: sprocket
31: coupling hole 32: keyway
33: damage prevention groove 34: pressure surface
35: pressurized surface dividing groove
H : Width (of keyway) h : Width (of breakage prevention groove)
D : (of keyway) depth d : (of breakage prevention groove) depth
W : Width (of the pressing surface)

Claims (3)

A medical device comprising a rotating shaft, a sprocket coupled to the rotating shaft to transmit the rotational power of the rotating shaft, and a key coupled to the rotating shaft and the sprocket so that the rotating shaft and the sprocket are fixed to each other, and installed in a medical device to transmit rotational power supplied from a driving source In the sprocket structure for the aircraft,
A keyway 32 is formed in the coupling hole 31 of the sprocket 30 to which the rotating shaft 10 is coupled,
At the inner edge of the keyway 32, a breakage prevention groove 33 is provided to prevent damage to the edge of the keyway 32 by preventing contact resistance with the edge of the key 20 from occurring when the key 20 is inserted. formed;
A pressing surface 34 is formed in the key groove 32 between the breakage prevention grooves 33 so as to be in surface contact with the corresponding surface of the key 20,
A pressing surface dividing groove 35 is formed on the pressing surface 34 to bisect the pressing surface 34 , so that when the key 20 is inserted, frictional resistance with the pressing surface 34 is reduced and the key 20 is inserted. A sprocket structure for medical devices, characterized in that the two divided pressing surfaces (34) are provided so as to be in surface contact with the corresponding surfaces of the key (20), respectively.
The method according to claim 1, The breakage prevention groove (33),
made in the shape of an arc,
When the width (H) of the keyway (32) is 3mm, the width (h) of the breakage prevention groove (33) is formed in a ratio of 0.75mm to 1.05mm,
When the depth (D) of the keyway (32) is 1.5mm, the depth (d) of the breakage prevention groove (33) is a sprocket structure for medical devices, characterized in that formed in a ratio of 0.2mm to 0.35mm.
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