RU185288U1 - PRESSURE ADJUSTMENT DEVICE FOR A WRITING INSTRUMENT AND A WRITING INSTRUMENT CONTAINING SUCH A DEVICE - Google Patents

Abstract

A pressure adjustment device for a writing instrument is proposed, comprising a deformable element. Small changes in air pressure in the tubular body of the writing instrument can be compensated by the deformation of the deformable element. Large changes in air pressure in the tubular body of the handle can also be compensated by moving the pressure control device. Thus, the tubular body of the writing instrument can prevent the occurrence of an imbalance in the internal air pressure caused by high outdoor temperature or low air pressure. Before the writing instrument is delivered by the manufacturer, the deformable element is already under pressure, as a result of which a slight change in the air pressure created when the writing instrument closes the pen cap balances the air pressure previously applied to the deformable body. Thus, after removing the pen cap, the ink located in the inner space of the inner chamber will not spill out and ink will not be excessively dispensed or leaked during writing.

Description

FIELD OF TECHNOLOGY

The present utility model relates to a pressure adjusting device for a writing instrument capable of delivering ink directly, in particular to a pressure adjusting device that can adjust pressure by moving relative to the writing instrument and / or warping. The present utility model also relates to a writing instrument comprising such a pressure adjusting device.

BACKGROUND

A conventional writing instrument capable of delivering ink directly comprises a tubular pen housing and a movable separator mounted in a tubular housing and dividing the interior of the tubular pen housing into an upper portion and a lower portion. The lower part forms the inner chamber, which is used to house ink and contains some air. The upper part forms a chamber communicating with the external environment, communicating with the outer space of the handle body through a ventilation hole formed at the far end of the tubular body of the handle. With the gradual expenditure of ink, the movable separator performs successive downward movements to ensure that the space previously occupied by the used ink is filled. However, the movable separator is made only with the possibility of slow small movement in accordance with the ink consumption, but not made with the possibility of regulating the internal pressure of the tubular body of the handle with significant pressure changes. In particular, large changes in pressure can occur, for example, in the following cases.

1. When a conventional writing instrument is exposed to high temperature, the air inside the tubular body of the pen may expand due to heating. Since when the pen cap is put on the tubular body of the pen, the air in the inner space of the inner chamber of the conventional writing instrument does not communicate with the outer space of the pen body, the air pressure in the inner space of the inner chamber of the conventional writing instrument increases due to the expansion of the heated air, which creates a pressure difference between the inner chamber of a conventional writing instrument and the outer space of the pen body. At this point, if the internal pressure of the tubular body of a conventional writing instrument is not properly adjusted, ink may spill out when the pen cap is removed. In another possible embodiment, in which a conventional writing instrument is used at high temperature, the air pressure generated by thermal expansion of the air can lead to excessive ink outflow and leakage. In addition, while gradually consuming ink during the writing process, the movable separator, although it makes sequential downward movements to ensure that the space previously occupied by the used ink, is filled, it rubs against the inner side wall of the pen tubular body, as a result of which the ink consumption does not correspond to the size of the movable stroke delimiter. Thus, as the ink is gradually consumed, the amount of air in the inner space of the inner chamber increases. Therefore, the air that has undergone thermal expansion has a large effect on the air pressure in the inner space of the inner chamber, and the ink leakage increases.

2. When the pen cap is put on the tubular body of the pen, the air pressure in the inner space of the inner chamber of a conventional writing instrument also increases slightly, which negatively affects the stability of a conventional writing instrument during transportation. Some changes in temperature and air pressure are inevitable during transportation, for example, during take-off and landing of an aircraft, or in the case when the vehicle experiences shock and vibration when it is on uneven ground. If the internal pressure of a conventional writing instrument is not properly adjusted, due to a change in air pressure, the pen cap may come off or even be squeezed out of the pen tubular body, or the ink may be ejected and leakage may occur, causing the surrounding things to get dirty.

DISCLOSURE OF THE ESSENCE OF A USEFUL MODEL

In view of the aforementioned disadvantages, the present utility model relates to a pressure adjusting device for a writing instrument and a writing instrument comprising a pressure adjusting device to overcome these disadvantages. The pressure control device is configured to control the internal air pressure in the writing instrument with minor and significant changes in pressure, which ensures the balance of the internal air pressure.

To solve the aforementioned problem, the pressure control device for the writing instrument according to the present utility model is mounted to move in the tubular body of the writing instrument and divides the inner space of the tubular body of the pen into an inner chamber and a chamber in communication with the external environment. The pressure control device comprises a tubular element adjacent its outer periphery to the inner side wall of the tubular body of the handle, and a deformable element placed in the tubular element. When the pressure difference between the inner chamber and the chamber communicating with the external environment exceeds the first predetermined value, the deformable element deforms in the direction of the chamber communicating with the external environment. When the pressure difference between the inner chamber and the chamber communicating with the external environment exceeds a second predetermined value, the pressure control device moves relative to the tubular body of the handle in the direction of the chamber communicating with the external environment. The second setpoint exceeds the first setpoint.

To solve the aforementioned problem, a writing instrument according to the present utility model comprises a tubular pen housing, a pressure adjusting device as described above, and a writing tip unit mounted on the open end of the tubular pen housing near the inner chamber of the tubular pen housing. The deformable element of the pressure control device is in advance under pressure, which allows the deformable element to resist deformation in the direction of the tubular body of the handle, which communicates with the external environment.

The pressure adjusting device and writing instrument according to the present utility model have the following advantages. Using a deformable element of the pressure adjusting device, a slight change in pressure can be compensated by deforming the deformable element. When the change in air pressure is significant, the change in air pressure can also be compensated by moving the pressure control device. Thus, regardless of the degree of change in air pressure, the pressure control device can adjust the air pressure inside the tubular body of the writing instrument to balance the air pressure, thereby preventing imbalance in the internal air pressure caused by high external temperature or low external air pressure. Accordingly, the ink located in the inner space of the inner chamber will not spill out when the pen cap is removed, and excessive dispensing or leakage during writing will not occur.

In addition, before the supply of the writing instrument according to the present utility model from the manufacturer, the deformable element is already under pressure, which allows the deformable element to resist deformation in the direction of the chamber in communication with the external environment. For example, the pressure adjusting device is under pressure to allow the deformable member to protrude in the direction of the inner chamber. Thus, when the writing instrument is closed with the pen cap, a slight change in air pressure corrects the air pressure previously applied to the deformable body, as a result of which the internal air pressure in the writing instrument comes to equilibrium. Thus, the writing instrument can be transported in a state in which the internal pressure and the external air pressure are balanced, while the influence of external temperature and air pressure can be minimized. Accordingly, the handle cap will not disconnect and will not be forced out of the tubular body of the handle due to changes in air pressure caused by shocks or vibrations during transportation. Excessive ink leakage will not occur, as a result of which the surrounding things will not get dirty and will remain unscathed.

When the pressure difference between the inner chamber and the chamber communicating with the external environment is less than the first predetermined value, the deformable element preferably protrudes in the direction of the inner chamber; when the pressure difference between the inner chamber and the chamber communicating with the external environment exceeds the first predetermined value, the deformable element protrudes in the direction of the chamber communicating with the external environment.

The deformable element is preferably in the form of a hemisphere.

The deformable element is preferably a diaphragm and has a first part and a second part; one end of the first part is connected to one end of the second part; the other end of the first part is connected to the inner side wall of the tubular element; the other end of the second part is formed as a closed end; wherein the inner diameter of the first part exceeds the inner diameter of the second part. When the deformable member protrudes in the direction of the inner chamber, the first part and the second part protrude in the direction of the inner chamber. When the deformable element protrudes in the direction of the chamber communicating with the external environment, the first part and the second part protrude in the direction of the chamber communicating with the external environment.

The deformable element preferably protrudes in the direction of the chamber, communicating with the external environment, and covers the inner space. When the pressure difference between the inner chamber and the chamber communicating with the external environment exceeds the first predetermined value, the deformable element deforms with expansion in the direction of the chamber communicating with the external environment, so that the volume of the internal space in this state is greater than when the pressure difference between the internal camera and the camera in communication with the external environment, less than the first specified value.

The deformable element is preferably an elastic shell that can expand under air pressure. The deformable element is compressed when the pressure difference between the inner chamber and the chamber communicating with the external environment is less than the first predetermined value. The deformable element expands in the direction of the chamber communicating with the external environment, with a pressure difference between the internal chamber and the chamber communicating with the external environment exceeding the first predetermined value.

The deformable element is preferably made in the form of a tubular bellows; one of the ends of the deformable element is connected to the inner side wall of the tubular element, and the other end of the deformable element is formed as a closed end. When the pressure difference between the inner chamber and the chamber communicating with the external environment exceeds the first predetermined value, the deformable element expands and lengthens in such a way that in this state it is longer than when the pressure difference between the inner chamber and the chamber communicating with the external environment is less first set value.

The change in external temperature corresponding to the first predetermined value is preferably in the range from 2 ° to 4 °, and the change in external temperature corresponding to the second predetermined value is in the range from 5 ° to 7 °.

The ratio between the diameter of the wide part of the deformable element and the thickness of the deformable element is preferably expressed by the following formula:

Y = 0.09X-0.1,

Where

X is the diameter of the wide part of the deformable element, and

Y is the thickness of the deformable element.

The thickness of the deformable element is preferably in the range of 0.35 mm to 0.8 mm, and the diameter of the wide part of the deformable element is in the range of 5 mm to 10 mm.

The outer periphery of the tubular element preferably includes an outer side wall and two annular protrusions. The annular protrusions are located at a distance from each other, are formed around the outer side wall of the outer periphery of the tubular element and protrude from it adjacent to the inner side wall of the tubular body of the handle.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a perspective view of a writing instrument according to the present utility model.

FIG. 2 is an exploded perspective view of the writing instrument shown in FIG. one.

FIG. 3-5 are schematic views of a working state of a writing instrument.

FIG. 6 and 7 are schematic views of an operational state of a pressure tool of a writing instrument according to a first embodiment of the present utility model.

FIG. 8 is a perspective view of a pressure tool of a writing instrument according to a second embodiment of the present utility model.

FIG. 9 and 10 are schematic views of the operational state of the pressure control device shown in FIG. 8.

FIG. 11 is a perspective view of a pressure adjusting apparatus of a writing instrument according to a third embodiment of the present utility model.

FIG. 12 and 13 are schematic views of the operational state of the pressure control device shown in FIG. eleven.

FIG. 14 is a perspective view of a pressure tool of a writing instrument according to a fourth embodiment of the present utility model.

FIGS. 15 and 16 are schematic views of the operational state of the pressure control device shown in FIG. fourteen.

IMPLEMENTATION OF A USEFUL MODEL

As shown in FIG. 1-3, a writing instrument according to the present utility model comprises a tubular pen body 10, a writing tip unit 20, and a pressure adjusting device 30 configured to control air pressure. In particular, the writing instrument according to the present utility model is a writing instrument supplying ink directly, in particular, it can be a marker pen, a pen for a white board, and the like.

In one preferred embodiment, the handle tubular body 10 has an interior space, an open end, and a vent. The open end and the ventilation hole are respectively located at two opposite ends of the tubular body 10 of the handle. In this preferred embodiment, the diameter of the tubular body 10 of the handle is in the range, in particular, from 4 mm to 25 mm.

The writing tip unit 20 is mounted on the open end of the tubular body 10 of the pen. In this preferred embodiment, the writing tip unit 20 includes a writing tip casing 21, a writing tip 22, an inner cotton pad 23, and a writing tip holder 24. The casing 21 of the writing tip is mounted on the open end of the tubular body 10 of the pen, while its inner end extends into the tubular body 10 of the pen. The writing tip 22 is installed in the casing 21 of the writing tip, while one end thereof extends from the casing 21 of the writing tip. The inner cotton filler 23 is installed in the writing tip casing 21 around the other end of the writing tip 22. The writing tip holder 24 is mounted on the inner end of the writing tip casing 21, inserted into the inner cotton filler 23 and securely holds the inner cotton filler 23. The detailed construction and structural relations of the block The 20 writing tips are traditional and are not limited to those described above.

As shown in FIG. 2 and 6, the pressure adjusting device 30 is mounted to move in the tubular body of the pen 10 and divides the interior of the tubular body 10 of the pen into a chamber 11 in communication with the external environment and the inner chamber 12. The inner chamber 12 is located closer to the writing tip unit 20, than chamber 11, and is filled with ink and air. The camera 11 communicates with the outer space of the handle body 10 through the ventilation hole. Thus, the air pressure in the chamber 11 and the air pressure in the outer space of the handle body 10 are balanced. The pressure adjusting device 30 includes a tubular member 31 and a deformable member 32.

The tubular element 31 is adjacent with its outer periphery to the inner side wall of the tubular body 10 of the handle. In this preferred embodiment, the outer periphery of the tubular element 31 includes an outer side wall and two annular protrusions 311. The annular protrusions 311 are spaced apart from each other, formed around the outer side wall of the outer periphery of the tubular element 31, and protrude from it adjacent to the inner the side wall of the tubular body 10 of the handle. In particular, the annular protrusions 311 are adjacent adjacent respectively to the two opposite open ends of the tubular member 31. However, the tubular member 31 is not structurally limited to the above-described pattern. For example, the annular protrusions 311 may be absent, while the outer side wall or other structural elements of the tubular element 31 may adjoin directly to the inner side wall of the tubular body 10 of the handle.

The deformable element 32 is a diaphragm and is located in the tubular element 31. When the air pressure in the inner chamber 12 of the handle tubular body 10 exceeds the air pressure in the chamber 11, if the pressure drop between the inner chamber 12 and the chamber 11 exceeds the first predetermined value, the deformable element 32 is deformed towards the camera 11, as shown in FIG. four; if the pressure difference between the inner chamber 12 and the chamber

11 exceeds the second predetermined value, the entire pressure adjusting device 30 moves relative to the tubular body 10 of the handle in the direction of the chamber 11, as shown in FIG. 5, wherein the second predetermined value exceeds the first predetermined value.

In other words, as further shown in FIG. 3-5, with a gradual increase in the pressure difference between the inner chamber 12 and the chamber 11, the deformable element 32 gradually deforms towards the chamber 11. When the deformable element 32 is deformed to the maximum value and the pressure drop continuously increases, the entire pressure control device 30 the movement relative to the tubular body 10 of the handle in the direction of the chamber 11. Thus, a slight change in pressure can be compensated by deforming the deformable element 32. When the change in air pressure is too large, the change in air pressure can also be compensated by moving the pressure adjusting device 30.

Deformable member 32 may have alternative designs to achieve the aforementioned effects. For example, below are two configurations for deformable member 32.

As shown in FIG. 6, 7, 9, and 10, a deformable member 32, 32A having a first configuration protrudes toward the inner chamber 12 or protrudes toward the chamber 11 when the air pressure changes. More specifically, when the pressure difference between the inner chamber 12 and the chamber 11 is less than the first predetermined value, the deformable element 32, 32A protrudes in the direction of the inner chamber 12; when the pressure difference between the inner chamber 12 and the chamber 11 exceeds the first predetermined value, the deformable element 32, 32A protrudes toward the chamber 11. In particular, there are two preferred embodiments for the first configuration of the deformable element 32, 32A, as described below.

As shown in FIG. 2, 6 and 7, the deformable element 32 may be in the form of a hemisphere, the direction in which the hemispherical deformable element 32 protrudes varies depending on the circumstances mentioned in the previous paragraph.

As further shown in FIG. 8-10, the deformable member 32A may have a first part 321A and a second part 322A. One end of the first part 321A is connected to one end of the part 322A. The other end of the first part 321A is connected to the inner side wall of the tubular element 31A. The other end of the second part 322A is formed as a closed end. The inner diameter of the first part 321A exceeds the inner diameter of the second part 322A. As shown in FIG.

10, when the deformable member 32A protrudes toward the inner chamber 12, the first portion 321A and the second portion 322A protrude towards the inner chamber 12. As shown in FIG. 9, when the deformable member 32A protrudes in the direction of the chamber 11, the first part 321A and the second part 322A protrude in the direction of the chamber 11.

As further shown in FIG. 11-16, in the second configuration of the deformable element 32B, 32C, the inner space enclosed in the deformable element 32B, 32C varies in volume with a change in air pressure. More specifically, the deformable member 32B, 32C remains protruding in the direction of the chamber 11 and encloses said interior space. When the pressure difference between the inner chamber 12 and the chamber 11 exceeds the first predetermined value, the deformable element 32B, 32C deforms with expansion in the direction of the chamber 11 so that the inner space in this state is larger in volume than when the pressure difference between the inner chamber 12 and camera 11, smaller than the first predetermined value.

In other words, the deformable element 32B, 32C is compressed when the pressure difference between the inner chamber 12 and the chamber 11 is less than the first predetermined value; the deformable element 32B, 32C expands when the pressure difference between the inner chamber 12 and the chamber 11 exceeds the first predetermined value. In particular, the second configuration of the deformable member 32B, 32C includes the following two embodiments.

As shown in FIG. 11-13, the deformable member 32B may be an elastic shell that can expand under air pressure. As shown in FIG. 13, the deformable member 32B is compressed at a pressure difference between the inner chamber 12 and the chamber 11 less than a first predetermined value. As shown in FIG. 12, when the pressure difference between the inner chamber 12 and the chamber 11 exceeds the first predetermined value, the deformable element 32B expands in the direction of the chamber 11.

As further shown in FIG. 14-16, the deformable element 32C is made in the form of a tubular bellows. One end of the deformable member 32C is connected to the inner side wall of the tubular member 31C. The other end of the deformable member 32C is formed as a closed end. As shown in FIG. 16, when the pressure difference between the inner chamber 12 and the chamber 11 is smaller than the first predetermined value, the deformable element 32C is compressed and shortened. As shown in FIG. 15, when the pressure difference between the inner chamber 12 and the chamber 11 exceeds the first predetermined value, the deformable member 32C expands and lengthens.

All deformable elements 32, 32A, 32B, 32C of the four above-mentioned embodiments can slightly adjust the air pressure by deforming in the direction of the chamber 11 when the pressure difference between the inner chamber 12 and the chamber 11 exceeds the first predetermined value. However, the deformable elements 32, 32A, 32B, 32C are not limited to the aforementioned two configurations and four embodiments, but provided that they allow solving the aforementioned problem according to the present utility model.

As further shown in FIG. 6, again, if we talk about the size of the deformable element 32, in this preferred embodiment, the ratio between the diameter of the wide part of the deformable element 32 and the thickness of the deformable element 32 is expressed by the formula: Y = 0.09X-0.1, where X is the diameter of the wide part deformable element 32, a Y is the thickness of the deformable element 32. Preferably, the diameter of the wide part of the deformable element 32 is in the range of 5 mm to 10 mm, and the thickness of the deformable element 32 is in the range of 0.35 mm to 0.8 mm. However, the size of the deformable member 32 is not limited to the above ranges and may be adjusted as necessary.

In addition, in this preferred embodiment, the deformable member 32 is made of silicone rubber. However, the material from which the deformable member 32 is made is not limited to silicone rubber. The deformable element 32 may be made of any material capable of achieving the aforementioned effect according to the present utility model.

With regard to compensation by the deformable member 32 of the differential pressure between the inner chamber 12 and the chamber 11, the first predetermined value and the second predetermined value can be determined by changes in the external temperature in addition to the differential pressure of the air. In particular, the change in external temperature corresponding to the first predetermined value is in the range from 2 ° to 4 ° and is preferably 3d; the change in external temperature corresponding to the second predetermined value is in the range from 5 ° to 7 ° and is preferably 6 °.

For example, when the outside temperature rises from 18 ° C to 21 ° C, the pressure drop between the inner chamber 12 and the chamber 11 may reach a first predetermined value; when the outside temperature rises from 18 ° to 24 °, the pressure drop can reach a second predetermined value. For example, when the external temperature rises from 25 ° to 28 °, the pressure drop between the inner chamber 12 and the chamber 11 may reach a first predetermined value; when the external temperature rises from 25 ° to 31 °, the pressure drop can reach a second predetermined value.

As further shown in FIG. 3 and 6, before the writing instrument according to the present utility model is shipped from the manufacturer, the deformable element 32 is already under pressure, which allows the deformable element 32 to resist deformation in the direction of the chamber 11. For example, in the first configuration of the deformable element 32, 32A of the device 30 the pressure control device 30, the pressure control is under pressure to allow the deformable element 32, 32A to protrude in the direction of the inner chamber 12. Thus, as further shown in FIG. 4 and 7, when the pen cap 40 covers the writing instrument, a slight change in air pressure corrects the air pressure previously applied to the deformable body 32, as a result of which the internal air pressure in the writing instrument is balanced. Thus, the writing instrument can be transported in a state in which the internal pressure and the external air pressure are balanced, while the influence of the external temperature and the external air pressure can be minimized. Thus, the cap 40 of the handle will not detach and will not be expelled from the tubular body 10 of the handle due to changes in air pressure caused by shocks or vibrations during transportation. Excessive ink delivery will not occur to cause a leak, as a result of which the surrounding things will not get dirty and will remain unscathed.

Returning to FIG. 5, when the external temperature is so high that the change in air pressure inside the writing instrument becomes excessive, the entire pressure control device 30 moves relative to the tubular body 10 of the pen in the direction of the chamber 11, thereby adjusting the air pressure inside the tubular body 10 of the pen. Small changes in air pressure can be controlled by deformation of the deformable element 32, and large changes in air pressure can be controlled by moving the pressure adjusting device 30.

Regardless of the degree of change in air pressure, the pressure control device 30 for the writing instrument according to the present utility model can adjust the air pressure inside the tubular body 10 of the writing instrument to balance the air pressure to prevent imbalance in the internal air pressure caused by high external temperature or low external air pressure. Thus, the ink located in the inner space of the inner chamber 12 will not flow outward when the cap of the pen 40 is removed and there will be no excessive dispensing or leakage during the writing process.

Claims (35)

1. A pressure adjusting device for a writing instrument, mounted to move the writing instrument in a tubular pen body for dividing the inner space of the pen tubular body into an inner chamber and a chamber in communication with the external environment, and comprising: a tubular element adjacent its outer periphery to the inner side wall of the tubular body of the handle, and a deformable element placed in the tubular element; wherein the deformable element is configured to deform in the direction of the camera communicating with the external environment, with a pressure difference between the internal camera and the camera communicating with the external environment exceeding the first predetermined value; wherein the pressure adjusting device is configured to move in the direction of the chamber in communication with the external medium relative to the tubular body of the handle with a pressure difference between the internal chamber and the external chamber in communication with the external medium exceeding the second predetermined value, moreover, the second predetermined value exceeds the first predetermined value. 2. The pressure adjustment device for a writing instrument according to claim 1, wherein the deformable element is configured to protrude in the direction of the inner chamber when the pressure difference between the inner chamber and the chamber communicating with the external environment is less than the first predetermined value; in this case, the deformable element is configured to protrude in the direction of the chamber communicating with the external environment, at a pressure difference between the internal chamber and the chamber communicating with the external medium exceeding the first predetermined value. 3. The pressure adjustment device for a writing instrument according to claim 2, in which the deformable element has the shape of a hemisphere. 4. The pressure adjustment device for a writing instrument according to claim 2, in which the deformable element has a first part and a second part, moreover, one end of the first part is connected to the end of the second part, the other end of the first part is connected to the inner side wall of the tubular element, the other end of the second part is formed as a closed end, and the inner diameter of the first part exceeds the inner diameter of the second part; wherein the first part and the second part are configured to protrude in the direction of the inner chamber when the deformable element protrudes in the direction of the inner chamber, wherein the first part and the second part are configured to protrude in the direction of the camera in communication with the external environment when the deformable element protrudes in the direction of the camera in communication with the external environment. 5. The pressure adjustment device for the writing instrument according to claim 1, in which the deformable element is configured to protrude in the direction of the chamber in communication with the external environment and cover the internal space; wherein when the pressure difference between the inner chamber and the chamber communicating with the external environment exceeds the first predetermined value, the deformable element is configured to deform with expansion in the direction of the chamber communicating with the external environment, so that the volume of the internal space in this state is greater than when the pressure difference between the inner chamber and the chamber, communicating with the external environment, less than the first specified value. 6. The pressure adjustment device for a writing instrument according to claim 5, in which the deformable element is an elastic shell made with the possibility of expansion under air pressure; wherein the deformable element is configured to contract when the pressure difference between the inner chamber and the chamber communicating with the external environment is less than the first predetermined value; and the deformable element is configured to expand in the direction of the chamber communicating with the external environment, with a pressure difference between the internal chamber and the chamber communicating with the external environment exceeding the first predetermined value. 7. The pressure adjustment device for a writing instrument according to claim 5, in which the deformable element is made in the form of a tubular bellows, one end of the deformable element is connected to the inner side wall of the tubular element, the other end of the deformable element is formed as a closed end; when the pressure difference between the inner chamber and the chamber communicating with the external environment exceeds the first predetermined value, the deformable element is configured to expand and lengthen in such a way that in this state it is longer than the difference in pressure between the inner chamber and the chamber communicating with the external medium less than the first specified value. 8. The pressure adjustment device for a writing instrument according to any one of paragraphs. 1-7, in which the change in external temperature corresponding to the first predetermined value is in the range from 2 ° C to 4 ° C; the change in external temperature corresponding to the second predetermined value is in the range from 5 ° C to 7 ° C. 9. The pressure adjustment device for a writing instrument according to any one of paragraphs. 1-7, in which the ratio between the diameter of the wide part of the deformable element and the thickness of the deformable element is expressed by the following formula: Y = 0.09X-0.1, where X is the diameter of the wide part of the deformable element, mm, and Y is the thickness of the deformable element, mm 10. The pressure adjustment device for a writing instrument according to claim 9, in which the thickness of the deformable element is in the range from 0.35 mm to 0.8 mm, and the diameter of the wide part of the deformable element is in the range from 5 mm to 10 mm. 11. The pressure adjustment device for a writing instrument according to any one of paragraphs. 1-7, in which the outer periphery of the tubular element has an outer side wall and two annular protrusions, while the annular protrusions are located at a distance from each other, are formed around the outer side wall of the outer periphery of the tubular element and protrude from it adjacent to the inner side wall of the tubular body of the handle.

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