RU2482789C2 - Device for pressure measurement, in particular for blood pressure measurement - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to medical equipment, namely to devices for pressure measurement. Device contains measuring mechanism and shock-absorbing device, which has enveloping element for measuring mechanism edge, located on the side of measuring mechanism bottom or on the side of threaded connection. Part of shock-absorbing device is located on the side of measuring mechanism, opposite to bottom or threaded connection. Spacer between measuring mechanism and part of shock-absorbing device, located on the side of measuring mechanism, is also included.

EFFECT: application of the invention makes it possible to improve protection of measuring mechanism from - shock-induced damage.

9 cl, 4 dwg

Description

The invention relates to a device for measuring pressure, in particular a device for measuring blood pressure, comprising a measuring mechanism and a shock-absorbing device.

Devices of the above kind are known, for example, from W0 2006/099578 A1. In this case, the shock-absorbing device is formed by a cup, called a clamp 320, in which the measuring mechanism is built-in. At the same time, the cup itself does not provide any cushioning effect if the force exerting it from the cup acts on the measuring mechanism.

In addition, similar shock absorbing devices in pressure measuring devices are known from US 2004/0083816 A1.

GB 2,180,944 discloses a device for measuring blood pressure with a measuring device strained in the axial direction.

US 1836682 discloses a shock absorber for pressure lines through which fluid flows in conjunction with a pressure measuring device.

No. 3,915,008 discloses a mounting device for protecting a measuring device against pulsation and pressure fluctuations.

US 2004/0083816 A1 discloses a device for measuring blood pressure with shock absorbing characteristics similar to those according to the aforementioned document WO 2006/099578 A1.

The basis of the invention is the modification of a pressure measuring device known from W0 2006/099578 A1 so that the measuring mechanism is better protected from damage due to impact or the like.

This problem is solved, according to the invention, due to the threaded connection for communication of the measuring mechanism with a shock-absorbing device.

Moreover, the invention is based on the understanding that a threaded connection provides a reliable connection of both parts connected to each other, namely, in all spatial directions. Thus, a threaded connection holds, for example, not only under compression load, but also under tensile load. Due to this, the measuring mechanism is reliably protected from damage due to shock or the like, namely, regardless of the direction in which the shock acts.

According to the invention, the measuring mechanism and / or the shock-absorbing device has / have an opening in which the internal thread of the threaded connection is made.

In other words, the internal thread of the corresponding threaded connection can preferably be performed on the measuring mechanism, on a shock-absorbing device, or both.

Similarly, according to the invention, it is preferable that the shock-absorbing device and / or the measuring mechanism has / have a protruding element on which the external thread of the threaded connection is made.

In addition, it is provided that the corresponding protruding element is located on the measuring mechanism, on the shock-absorbing device, or both.

The internal and / or external thread of the threaded connection is preferably made integrally with a measuring mechanism or a shock-absorbing device.

This embodiment has the advantage of fewer parts.

Additionally or as an alternative solution, it may also be provided that the internal thread of the threaded connection is made on the threaded insert.

Such a threaded insert is, according to the invention, preferably located in that opening of the measuring mechanism or shock-absorbing device, within which the internal thread for the threaded connection should be located.

Moreover, according to the invention, it is further preferred that the pressure measuring device comprises a housing, the threaded insert pushing the protrusion on the shock-absorbing device into the undercut in the housing.

In other words, in this embodiment, the threaded insert is used not only as part of the threaded connection, but also to hold the shock absorbing device on the housing.

Furthermore, according to the invention, a housing is provided on the measuring device, wherein the shock-absorbing device is fixed to the housing.

This fastening can be carried out in any way, in particular by means of a geometric closure, frictional closure or using fasteners.

According to one particularly preferred embodiment of the invention, the internal thread of the threaded connection is made on the inner wall of the channel through which the measuring mechanism is connected to the external environment. Thus, the channel is used for two purposes, namely, on the one hand, to connect the measuring mechanism to the external environment, and, on the other hand, to accommodate the internal thread.

To connect the measuring mechanism with the external environment, for example, it can be provided that a gas (air), the pressure of which is to be measured, is supplied to the measuring mechanism through a channel. However, the channel can also be used to transmit a mechanical measurement value, for example, due to the fact that it has a shaft that rotates depending on pressure. Finally, lines, such as electric wires for transmitting measurement values, can also be placed in the channel.

Preferably, a device is provided for protecting the measuring mechanism from rotation relative to the shock-absorbing device.

This rotation protection serves to ensure the accuracy of the (readable) measurement result.

The anti-rotation device is, according to the invention, preferably profiled. In other words, it is based on the principle of frictional and / or geometric closure. Profiling can be edges, waves, or the like.

In addition to the threaded connection indicated above, to solve the problem according to the invention, an improved protection of the measuring mechanism against damage due to impact or the like is provided. the fact that the shock-absorbing device has a female element for the edge of the measuring mechanism located on the bottom side of the measuring mechanism or on the threaded connection side, as well as other features according to independent point 1.

If a threaded connection is provided, then the bottom side of the measuring mechanism coincides with the threaded connection side.

In this case, the female element extends around the measuring mechanism, preferably along the edge.

In other words, it is contemplated that the female member completely surrounds the measuring mechanism in the circumferential direction. Due to this, the covering element can serve not only for cushioning, but also for sealing the measuring mechanism.

In addition, an opening bevel is provided on the female member.

This embodiment simplifies the insertion of the measuring mechanism into the female member.

In turn, a device for protecting against rotation of the measuring mechanism relative to the enclosing member in order to increase the measurement / reading accuracy can be preferably provided according to the invention.

The rotation protection device may have profiling, which may be ribs, waves, or the like.

The female element can in principle be made in any way. In particular, it can be made as a single unit with that part of the shock-absorbing device, which serves for screwing. According to the invention, it is preferably mounted on the housing of the pressure measuring device.

Such fastening can be performed arbitrarily, in particular by means of frictional closure, geometric closure or by means of fasteners.

According to the invention, the (other) part of the shock-absorbing device is adjacent to the bottom or to the opposite side of the threaded joint of the measuring mechanism.

Although, as already detailed above, a threaded connection already provides protection against impacts from all spatial directions, it may be preferable or even necessary to carry out such additional protective measures.

In this case, the (other) part of the shock-absorbing device can in turn be formed by a separate structural element or a separate unit. However, it can also be made in a single unit with a female element and / or part of a shock-absorbing device coordinated with a threaded connection.

In addition, a spacer is provided between the measuring mechanism and the side of the measuring mechanism adjacent to the bottom or opposite the threaded connection to the part of the shock-absorbing device.

Such a spacer creates space between the individual parts of the shock-absorbing device for accommodating the measuring mechanism. This space is preserved, for example, also when the structural element or unit of the shock-absorbing device experiences a compression load. Such a compression load (prestress) may be appropriate to increase the sealing of the measuring mechanism.

To increase the accuracy of measurement / reading, according to the invention, again, a device is provided for protection against rotation of the spacer relative to the measuring mechanism.

For the same reason, according to the invention, a device for protecting against rotation of the reading scale relative to the spacer is preferably provided.

Due to this rotation protection, rotation of the reading scale relative to the measuring mechanism is also excluded, so that the measurement / reading accuracy is maintained.

According to the invention, at least one part of the shock-absorbing device preferably has a Shore A hardness of 40 ° -80 °.

Finally, at least one part of the shock-absorbing device has one or more of the following materials:

- synthetic rubber, preferably nitrile butadiene rubber (NBR),

- tripolymer elastomer (rubber), preferably ethylene-propylene-diene rubber (EPDM),

- silicone.

With a suitable choice of size, both dimensions and stiffness, in the device for measuring pressure according to this invention, shock resistance is achieved, corresponding to a free fall from a height of up to 1.5 m.

The following is a further explanation of the invention based on exemplary embodiments with reference to the accompanying drawings, in which:

figure 1 - parts of a device for measuring blood pressure, according to one preferred embodiment of the invention, in an exploded isometric view;

figure 2 is the same as in figure 1, however, according to another example embodiment of the invention;

figure 3 is the same as in figures 1 and 2, however, according to another example embodiment of the invention;

figure 4 is the same as in figure 1-3, however, according to another example embodiment of the invention.

As shown in FIG. 1, the blood pressure measuring device comprises a measuring mechanism 10, covering the element 12 for the edge 140 of the measuring mechanism, a shock absorber 14, a housing 16 and a threaded insert 18. The covering element 12 has an inlet bevel 20 to facilitate the introduction of the measuring mechanism 10 into female element 12. A protruding element 22 with an external thread 24 is made on the measuring mechanism 10. The threaded insert 18 has a corresponding internal thread 26. At the bottom 28 of the housing 16, a protruding element 30 with an undercut 32 is made . In the assembled state, the threaded insert 18 presses the protrusion 34 into the undercut 32, so that the shock absorber 14 is held in geometrical closure on the housing 16.

The device for measuring blood pressure according to figure 2, essentially made the same as the device according to figure 1. Namely, in particular, it has a shock absorber 14 with a threaded insert 18, as well as a female member 12. However, a shock absorber 40 additionally supported through the dial 36, a spacer 38 and a measuring mechanism on the shock absorber 14 is provided. The shock absorber 40 with an intermediate arrangement of a transparent plastic disc 42 pushed down by the locking ring 44 in FIG. 2 by screwing the locking ring 44 onto the housing 16. For this, an internal thread is provided (not shown) on the locking ring 44, while the housing 16 has (not shown) Agen) an external thread.

The pre-stress acting on the shock absorbers 14 and 40, as well as on the female element 13, contributes to sealing the device for measuring blood pressure.

The embodiment of FIG. 3 essentially corresponds to the embodiment of FIG. 2, however, does not have a shock absorber 14 with a threaded insert 18. Therefore, a protruding element 22 is also not provided on the measuring mechanism. Thus, in the exemplary embodiment of FIG. 3, only the shock absorber 40 as well as the enclosing member 12 serve to protect against impacts and to seal.

Figure 4 shows an exemplary embodiment in which the female member 12 is integral with the shock absorber 14. You can see the channel 46, which serves to supply air to the measuring mechanism 10, the pressure of which is to be measured. The extension of the channel 46 is formed by a channel 48, which coincides with the interior of the threaded insert 18. Although not shown in the drawing, the measuring mechanism has another channel through which it is connected to the channel 48 and, accordingly, 46.

As shown in FIGS. 2 and 3, on the dial disk 36 there is a rotation protection 50 in the form of a protrusion that fits into the corresponding groove (not shown) of the spacer 38. The rotation protection performed on the spacer 38 is indicated by 51.

In addition, there are still other rotation protection, which are not shown in the drawing. So, on the enclosing element 12, the shock absorber 14 and the shock absorber 40, surfaces with wave-like profiling are provided in order to protect against rotation of adjacent structural elements (body 16, measuring mechanism 10, spacers 38 and / or threaded insert 18).

Disclosed in the above description, the claims, and also in the drawings, the features of the invention can be significant both individually and in any combination for the implementation of the invention in its various embodiments.

Claims (10)

1. A device for measuring pressure, comprising a measuring mechanism and a shock absorbing device, characterized in that the shock absorbing device has a covering element for the edge of the measuring mechanism located on the bottom side of the measuring mechanism or on the side of the threaded connection provided for communication of the measuring mechanism with the shock absorbing device, this part of the shock-absorbing device is located on the side of the measuring mechanism, opposite the bottom or threaded connection, and A spacer is provided between the measuring mechanism and the part of the shock-absorbing device located on the side of the measuring mechanism, opposite the bottom or threaded connection. 2. The device according to claim 1, characterized in that the female element passes around the measuring mechanism along the edge. 3. The device according to claim 1 or 2, characterized in that the introducing bevel is provided on the female element. 4. The device according to claim 1 or 2, characterized in that it provides a device for protecting against rotation of the measuring mechanism relative to the enclosing element. 5. The device according to claim 4, characterized in that the device for protection against rotation has a profiling. 6. The device according to claim 1, characterized in that it provides a housing, while the enclosing element is mounted on the housing. 7. The device according to claim 1, characterized in that it provides a device for protection against rotation of the spacer relative to the measuring mechanism. 8. The device according to claim 1, characterized in that it provides a device for protection against rotation of the reading scale relative to the spacer. 9. The device according to claim 1, characterized in that at least one part of the shock-absorbing device has a Shore A hardness of 40-80 °. 10. The device according to claim 1, characterized in that at least one part of the shock-absorbing device has one or more of the following materials:
- synthetic rubber, preferably nitrile butadiene rubber (NBR),
- tripolymer elastomer (rubber), preferably ethylene-propylene-diene rubber (EPDM),
- silicone.

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