DE1918716A1 - Body-borne sound pick-up device - Google Patents

Description

Hearing-borne sound pick-up device in the known method according to Riva-Rocci-Korotkoff auscultatory blood pressure measurement is carried out with the help of the otethoskopes, whereby the most favorable point of removal is determined by very precise palpation must become.

A structure-borne sound microphone is used to improve the sound pick-up. which either together with the blood pressure cuff or separately with one Elastic band is applied. The structure-borne sound microphone mainly consists of one Crystal collector, which against impact, strong pressure and excessive tension on the discharge cable is very sensitive. The separate guiding of the pneumatic one makes itself disadvantageous and electrical connection from the extremity to the blood pressure measuring apparatus noticeable.

which experience shows should be based on these descriptions a better and safer distal removal can be created. There is therefore the Task to develop a device in which the structure-borne sound microphone against Impact, shock, pull and pressure is protected. The acceptance sensitivity of the structure-borne sound microphone must not be affected by this. The contact pressure of the microphone pickup should have a constant defined value.

This system with a pressure component should be independent of the relative Be the pressure in the blood pressure cuff. werner should switch the compressed air supply to the Blood pressure cuff and the cable lead from the distal structure-borne sound microphone can be run together in a single variable connection.

According to the invention, the object is achieved in that the Structure-borne sound microphone in a housing protected against the use of external force firmly inserted into the blood pressure cuff, the cable lead from the microphone through the rubber bladder of the ..cuff, sealed against atmospheric pressure, in the air pressure hose inserted and in this up to the connection device on the blood pressure measuring apparatus is directed. The structure-borne sound microphone is attached in an open box. which is connected to an outer housing via damping elements.

The housing, which is open to the inside of the cuff, is fixed to the Connected inside of the cuff cover.

It protects the structure-borne sound microphone against impact and shock while through the damping elements, the pressure applied by the microphone pick-up to the tissue receives a constant value regardless of the relative pressure in the cuff, so that the decrease sensitivity of the structure-borne sound microphone is not disturbed. the Structure-borne sound microphone unit, socket, damping element and housing can also be used placed outside the blood pressure cuff a short distance from its lower edge and is therefore independent of the cuff pressure. This increases the tension between the arteries and the tissue not so much constricted as in the case of the structural unit that is firmly inserted into the cuff. The housing with the protected built-in structure-borne sound microphone is on one Fastened guide bracket, which is connected to the blood pressure cuff. When the cuff is put on, the guide bracket also attaches the structure-borne sound microphone to the extremity of the body. Due to the damping elements between the box and Housing is a precisely defined contact pressure on the tissue during the measurement available. The lead cable in front of the microphone is inserted into the rubber bladder as described above introduced and vulcanized.

The structure-borne noise cut-off device can also be used separately without a connection with the blood pressure cuff applied to the extremity by pulling on a Anleg spreading clamp is attached, the type and size depending on the contact point on Body can be designed differently for brachial or pulse decrease. The down lead the microphone in this case is different from the previous and the following Description run separately from the air pressure hose.

The electrical discharge cable is through from the structure-borne sound microphone corresponding openings in the can and the housing through the wall of the rubber bladder guided and vulcanized, drawn into the air pressure hose and through this to to the connection to the blood pressure meter. The pneumatic and electrical connection from the cuff to the blood pressure measuring device is thus in a single line housed, which in addition to the easier handling of the apparatus, is particularly also the electrical discharge cable is protected and the harmful tensile stress on the structure-borne sound microphone is prevented.

When the apparatus is not in use, a cover closes the housing to protect the structure-borne sound microphone.

The connection. device on the blood pressure measuring device into which the air pressure hose ends with the electrical cable, has to fulfill two tasks. The compressed air Both the electrical impulses and the Housing wall into the interior of the blood thickening apparatus to the measuring points.

According to the invention, it must be ensured that the plug and screw connection with safe electrical.contacts hermetically sealed, well locked, and the electrical cable, whether single or multi-strand, is attached with strain relief.

The coupling piece consists of two main parts, the socket, which is mounted in a bore of the sphygmomanometer housing, and the plug, which for example, is brought into connection with a union nut with the socket.

Inside the socket there is a plug pin with a shielding socket or there are several electrical connector pins in an insulating body with air ducts stored, the electrical lines are sealed to solder contacts by the Bushing led into the interior of the apparatus, while on a hose connector of the The air pressure hose to the blood pressure meter is pulled up.

The plug contains a socket with shield and strain relief for a single-core cable or a multi-core, strain-relieved cable with a corresponding Number of sockets, stored in an insulating body with air ducts, as well a sealing ring for sealing the socket against the plug by means of a union nut or a latch, optionally also a plug lock. On a hose connector the air pressure hose coming from the fan sleeve is pulled up.

Fig, 1 shows the cuff in approximately natural size in section the structure-borne noise microphone in the protective housing and the one in the air pressure hose Lead wire up to the connection to the blood pressure measuring device.

In Fig. 2 and 3, the connection is as a plug and a socket in the enlarged Scale shown.

The structure-borne sound microphone 1 is in FIG. 1 towards the inside the cuff open box 2 attached, which via the damping elements 3 with the housing 4 is in connection. The one open to the inside of the cuff housing 4 is firmly connected to the inner skin 5 of the cuff and is used for gout to protect the structure-borne sound microphone 1 with a cover not shown here locked.

The electrical discharge cable 6 penetrates the rubber bladder 7, with the it is vulcanized airtight, on the one hand leads through holes provided in the housing 4 and in the socket 2 to the structure-borne sound microphone 1, and on the other hand is in the air pressure hose 8 of the rubber bladder 7 inserted into it, in which it is connected to the blood pressure measuring apparatus to be led.

The connection of the air pressure hose combined with the discharge cable 6 8 takes place in Fig. 2 on the hose olive 9 of the plug 10 with the union nut 11.

The discharge cable 6 is soldered to the socket contact 12, which is located in the Teflon insert 13, which in turn is after the soldering is firmly and airtightly connected to the guide bushing 14 by means of phenolic resin.

The threaded handle 15 is screwed onto the slotted shielding sleeve 16 and thus fastened at the same time the insulating body 17 with the air ducts 18, the is guided in the connector 10, fastened with the sealed screw 19 and on his the front edge of the ring carries the sealing ring 20. By screwing the threaded sleeve 15 with the shielding bushing 16, the guide bushing 14 is against the slotted clamping bushing 21, which is firmly attached to the shielding of the discharge cable via a cone 22 5 presses and thus at the same time the electrical contact of the shielding of the Discharge cable 6 to the shielding socket 16 and the strain relief produces.

The clamping device as described is not required for multi-core cables. For this, the multi-core cable is then attached to the screw with a sealed screw provided threaded hole 23 for strain relief clamped while the insulating body 17 normal distributed according to the number of cable cores on its face Low frequency socket contacts.

Fig. 3 shows the socket 24 in which the insulating ring body 25 with air channels 26 frozen and fastened with the sealed screw 27. Through him the Shielding sleeve 28 centered and fastened with the retaining ring 29.

With the shielding sleeve 28 is the Teflon insert 30 and the plug contact 31 firmly connected. From this una from the shielding sleeve 28 lead sealed electrical lines through the socket 24 to the solder contacts 32. On the hose olive 33, the hose 34 leading to the blood pressure manometer is pulled.

The socket 24 is through a hole in the sphygmomanometer housing wall 35 and fastened with the nut 36 shown in FIG. 1.

When screwing the plug 10 to the socket 24, both parts by the union nut 11, which is also designed as a bolt or plug-in closure can be sealed against the atmospheric air by means of the sealing ring 20, while the compressed air from the apparatus through the hoses and air ducts to the cuff arrives and the electrical impulses from the structure-borne sound microphone 1 via the discharge cable 6, socket and plug contacts are given to the apparatus.

In the case of multi-core cable routing, the shielding bushing 28 is not required. The insulating ring body / 25 then takes according to the number of cable cores distributed on its face normal low-frequency plug contacts. The shielding socket 16 is also omitted, the insulating body 17 then receives the plug sockets on its end face.

In Fig. 4, the audible sound pick-up device is outside.

half of the blood pressure cuff shown. The housing 4, which the Structure-borne sound microphone with socket and damping elements is located in the short distance from the lower edge of the cuff and is on the steering handle 37 attached, which with the blood pressure cuff 39, here wrapped around the extremity 40, is in firm connection. The derivation cable 6 leads from the structure-borne sound microphone in the rubber bladder of the cuff with which it is vulcanized against the atmospheric Pressure is sealed, and further into the air pressure hose 8 until it is connected the blood pressure monitor.

Fig. 5 shows the spreading clamp 38 made of spring material on which the housing 4 with structure-borne sound microphone, socket and damping elements attached is. The spreading clamp 38 is resiliently around the extremity 40 and pushes the structure-borne sound microphone on the tissue. Through the damping elements between the box and housing is a precisely defined contact pressure on the tissue during the measurement admitted. The type and size of the spreading clamp 38 can be designed in different ways and enables a structure-borne sound or pulse rate to be taken on each extremity of the Body. In this embodiment, the discharge cable 6 is again separate from the air pressure hose 8 led.

Claims (10)

Claims Structure-borne sound acceptance device for acoustic acceptance of functions on the extremities of the human body, especially on the brachialis for Blood pressure measurement, pulse decrease or other structure-borne noise determination by means of electronic Pickup, characterized in that the structure-borne sound microphone (1) is of various types Consists of a crystal, a capacitor or an inductive structure-borne sound pick-up in one Can (2) open to the take-off point by damping elements (3), which reduce the contact pressure of the structure-borne sound microphone (1) on the tissue regardless of the relative pressure in the blood pressure cuff received at a constant value, with an open housing (4) connected, protected by this against impact, shock, tension and overpressure in the Inner skin of the blood pressure cuff permanently installed and with a when not in use The cover is closed, the discharge cable (6) is sealed against atmospheric pressure, into the rubber bladder (7) of the blood pressure cuff and the air pressure hose connected to it (8) introduced and vulcanized and in the protection of this as the only connection of the cuff to the blood pressure measuring device together with the air pressure hose (8) the represents electrical and pneumatic feed. 2. Structure-borne noise pickup device according to claim 1, characterized in that that build inhe it structure-borne sound microphone (1), socket (2), damping elements (3) and Housing (4) to reduce the arterial tissue tension independent of the Uanschette pressure outside of the blood pressure cuff, but with it at a short distance connected from the lower edge by a guide bracket (37) and the discharge cable (6) from the structure-borne sound microphone (1) into the rubber bladder (7) and vulcanized is, with a precisely defined contact pressure due to the damping elements (3) the tissue is present during the measurement. 3. Body-borne sound removal device according to claim 1 and 2, characterized in that that the hearing-borne sound microphone (1) is attached in a box (2) open to the acceptance point and via a central also two or more on the Kand the can (2) and Damping elements (3) consisting of GuMmi, plastic or metal springs, which enable a precisely defined contact pressure on the tissue during the measurement, a housing (4) open to the tapping point to protect against external use of force such as impact, Is installed protected against shock, pull or overpressure. 4. Structure-borne sound pickup device according to claim 1 to 3, -thereby characterized in that the discharge cable (6), from the structure-borne sound microphone (1) through Openings in the box (2) and the housing (4) through the wall of the rubber bladder (7), sealed against atmospheric air, inserted into the compressed air hose (8) and is forwarded to the connector (10). 5. structure-borne sound pickup device according to claim 1 to 4, d a d u It is noted that the air pressure hose (8) with the discharge cable (6) are connected together with the plug (10), the discharge cable (6) in the Buchsehkontakt (12) opens, a clamping socket (21) the shielded discharge cable (6) relieved of strain and at the same time the electrical contact to the shielding socket (16) manufactures, whereby the air pressure hose (8) on the hose olive g9) of the plug g10) is pulled, 6. Structure-borne noise pickup device according to claim 1 to 5, characterized characterized in that the clamping device in the plug (10) with the socket contact (12) as well as Teflon insert (13) and the shielding bushing (16) in an insulating body (17) is centered with air channels (18). 7. structure-borne noise pickup device according to claim 1 to 6, d a d u notify that a shielding socket (28) in the socket (24) with plug contact (31) in the Teflon insert (30) through an insulating ring body (25) is centered with air ducts (26) and the electrical lines from the plug contact (31) and the shielding bushing (28) isolated and sealed by the bushing (24) lead to the solder contacts (32). 8. Structure-borne sound pickup device according to claim 1 to 7, d a d u It is noted that the plug (10) is secured by means of a union nut (11) or other lock, optionally plug-in connection, with the one on the sphygmomanometer housing attached socket (24) and connected by the seal ring (20) against the atmospheric Pressure is sealed, the compressed air from the apparatus via the socket (24) through the air channels (26) to the plug (10), through the air channels (18) and the compressed air hose (8) continues to reach the cuff while the electrical impulses from the structure-borne sound microphone (1) Liier the discharge cable (6), the socket contact (12) with shielding socket (16) in the Plug (10) and the plug contact (31) with shielding socket (28) in the socket (24) be added to the leak points in the apparatus. 9. Structure-borne sound pickup device according to claim 1 to 8, characterized characterized in that instead of a single-core shielded electrical bushing Multi-core cables with a corresponding number of sockets and plugs on the front sides the insulating body (17) and the insulating ring body (25) are connected. 10. Structure-borne noise pickup device according to claim 1 and 3, characterized characterized in that the structural unit-it structure-borne sound microphone (1), box (2), damping elements (3) and housing (4) is attached to a spreading clamp (38) which, depending on Type and size for the brachial or pulse decrease on each limb of the body attached and the discharge cable (6) in this case separate from the air pressure hose (8) to be led.