Body pulsating apparatus

Abstract

A vest for a human body has an air core coupled to a pulsator operable to subject the vest to air pressure pulses which applies and releases pressure to the human body. The vest has a cover having a pocket accommodating the air core. The pulsator has diaphragms connected to a d.c. electric motor with a rotary to reciprocating motion transmitting mechanism operable to generate air pressure pulses which are transmitted to the air core which applies repetitive pressure pulses to the human body.

Description

FIELD OF THE INVENTION

The invention is directed to a medical device used to apply repetitive compression forces to the body of a person to aid blood circulation, loosening and elimination of mucus from the lungs of a person and relieve muscular and nerve tensions.

BACKGROUND OF THE INVENTION

Artificial respiration devices for applying and relieving pressure on the chest of a person have been used to assist in lung breathing functions, and loosening and eliminating mucus from the lungs. Subjecting the person's chest and lungs to pressure pulses or vibrations decreases the viscosity of lung and air passage mucus, thereby enhancing fluid mobility and removal from the lungs. These devices use vests having air-accommodating bladders that surround the chests of persons. Mechanical mechanisms, such as solenoid or motor-operated air valves, supply air under pressure to the bladders in regular patterns of pulses. J. D. Ackerman et al in U.S. Pat. No. 2,588,192 disclose an artificial respiration apparatus having a chest vest supplied with air under pressure with an air pump. Solenoid-operated valves control the flow of air into and out of the vest in a controlled manner to pulsate the vest, thereby subjecting the person's chest to repeated pressure pulses. W. J. Warwick and L. G. Hansen in U.S. Pat. No. 5,056,505 disclose a chest compression apparatus having a chest vest surrounding a person's chest. A motor-driven rotary valve allows air to flow into the vest and vent air therefrom to apply pressurized pulses to the person's chest.

R. S. Dillion in U.S. Pat. No. 4,590,925 uses an inflatable enclosure to cover a portion of a person's extremity, such as an arm or leg. The enclosure is connected to a fluid control and pulse monitor operable to selectively apply and remove pressure on the person's extremity. R. L. Weber in U.S. Pat. No. 3,672,354 discloses a rest inducing device having an air mattress supplied with air in pulses from an air pump at the frequency of the person's heartbeat.

C. N. Hansen in U.S. Pat. Nos. 5,453,081 and 5,569,170 discloses an air pulsating apparatus for supplying pulses of air to an enclosed receiver, such as a vest or an air mattress. The apparatus has a casing with an internal chamber containing a diaphragm. A solenoid connected to the diaphragm is operated with a pulse generator to move the diaphragm to pulse the air in the chamber. A hose connects the chamber with the vest to transfer the air pulses to the vest. This apparatus requires a sizeable solenoid which is relatively heavy and uses considerable electrical power. The solenoid generates heat and noise. The body pulsating apparatus of the present invention overcomes the weight, noise and heat disadvantages of the prior air pulsating apparatus.

SUMMARY OF THE INVENTION

The invention comprises a jacket used to apply repetitive pressure pulses to a human body and a pulsator for generating air pressure pulses that are transmitted to the jacket. The jacket has an outer cover attached to a flexible liner. An air core of flexible material located between the cover and liner is connected with a hose to a pulsator operable to generate repetitive air pressure pulses which are transmitted to the air core. The air pressure pulses subjected to the air core create repetitive pressure pulses that are transmitted to the body of a person wearing the jacket. The pulsator has a casing with an internal chamber in air communication with the hose. A diaphragm open to the internal chamber is connected to a motion transmitting mechanism which moves the diaphragm relative to the internal chamber to sequentially increase and decrease the pressure of the air in the internal chamber thereby generating air pressure pulses. An electric motor drives the motion transmitting mechanism which moves the diaphragm. A motor control regulates the speed of the motor to control the air pressure pulse rate.

The preferred embodiment of the pulsator has a casing with an internal chamber with first and second diaphragms. A check valve, such as a reed valve or flapper valve, mounted on the casing allow air to flow into the chamber responsive to movements of the diaphragms. A motion transmitting mechanism driven with an electric motor has a pair of cams and cam followers connected to the diaphragms operable to reciprocate the diaphragms thereby generating air pressure pulses in the internal chamber. The air pressure pulses are transferred to the air core of the vest which applies repetitive pressure pulses to the body of the person. A motor control regulates the speed of the motor to control the air pressure pulse rate.

DESCRIPTION OF THE DRAWING

FIG. 1 is a diagrammatic view of the body pulsating apparatus located on a body of a person;

FIG. 1A is an enlarged end view of the right end of the air pulsator of FIG. 1 ;

FIG. 2 is a diagrammatic view, partly sectioned, of the jacket of the body pulsating apparatus of FIG. 1 ;

FIG. 3 is an outside plan view of the jacket of FIG. 2 ;

FIG. 4 is an inside plan view of the jacket of FIG. 3 ;

FIG. 5 is a bottom view of the jacket of FIG. 4 ;

FIG. 6 is a plan view of the inside of the jacket, partly sectioned, showing the air core;

FIG. 7 is a plan view of the air core of the body pulsating apparatus;

FIG. 8 is a bottom view of the air core of FIG. 7 ;

FIG. 9 is a sectional view taken along the line 9 — 9 of FIG. 8 ;

FIG. 10 is a sectional view taken along the line 10 — 10 of FIG. 7 ;

FIG. 11 is a sectional view taken along the line 11 — 11 of FIG. 9 ;

FIG. 12 is an enlarged sectional view of the air pulsator taken along line 12 — 12 of FIG. 1 ;

FIG. 13 is an enlarged and foreshortened sectional view taken along the line 13 — 13 of FIG. 12 ;

FIG. 14 is an enlarged sectional view taken along the line 14 — 14 of FIG. 13 ;

FIG. 15 is a reduced sectional view taken along the line 15 — 15 of FIG. 12 ; and

FIG. 16 is a foreshortened sectional view taken along the line 16 — 16 of FIG. 15 .

DESCRIPTION OF PREFERRED EMBODIMENT

The body pulsating apparatus 10 , shown in FIG. 1 , functions to apply repetitive pressure pulses to a person 11 having an upper body 13 and left and right shoulders 12 and 14 . A diaphragm 16 extends across the body below lungs 17 and 18 .

A jacket 24 located about body 13 has an outside cover 26 joined to an inside liner 27 . Cover 26 is a non-elastic fabric. Liner 27 is an open mesh flexible sheet member secured to outer peripheral edges of cover 26 . Fasteners, shown as stitches 25 in FIG. 6 , connect liner 27 to cover 26 and a bottom zipper 51 . An air core 28 confined between cover 26 and liner 27 operates to apply repeated fluid, herein air, pressure pulses, shown as arrows 33 and 34 , to body 11 . The frequency of the pulses is variable. The pressure of the air varies between 0.25 psi to1 psi. Air core 28 can be subjected to other air pressures.

An air pulsator 29 connected to jacket 24 with air hose 31 delivers air under pressure to air core 28 . Hose 31 is connected to a tube 32 attached to jacket 24 . The end of hose 31 telescopes over tube 32 to releasably connect hose 31 to jacket 24 . The air pressure delivered to air core 28 periodically increases and decreases to apply pressure pulses to body 13 . The details of pulsator 29 are hereinafter described.

As shown in FIG. 3 , jacket 24 has a pair of upright shoulder straps 36 and 37 laterally separated with a concave upper back edge 38 . Upright front chest portions 39 and 46 are separated from straps 36 and 37 with concave curved upper edges 41 and 47 which allow jacket 24 to fit under the person's arms. Loop pads 42 and 48 secured to the outer surfaces of chest portions 39 and 46 cooperate with hook pads 52 and 53 secured to the insides of shoulder straps 36 and 37 to releasably connect shoulder straps 36 and 37 to chest portions 39 and 46 . As shown in FIG. 1 , shoulder straps 36 and 37 extend forwardly over shoulders 12 and 14 and downwardly over chest portions 39 and 46 . The hook and loop pads 42 , 48 , 52 and 53 are releasable VELCRO fasteners that connect shoulder straps 36 and 37 to chest portions 39 and 46 and hold chest portions 39 and 46 adjacent the front of body 13 .

Jacket 24 has a first lateral end flap 43 extended outwardly at the left side of jacket 24 . A rectangular loop pad 44 secured to the outside of flap 43 cooperates with hook pads 54 and 56 on a second lateral end flap 49 on the right side of jacket 24 to hold jacket 24 around body 13 . The hook and loop pads 44 , 54 and 56 are VELCRO fasteners that allow jacket 24 to be tightly wrapped around body 13 .

Air core 28 , shown in FIG. 6 , conforms to the shape and contour of the space between cover 26 and liner 27 . As shown in FIGS. 7 and 8 , air core 28 has a pair of upright back sections 96 and 97 that fit into pockets in shoulder straps 36 and 37 and upright front sections 98 and 99 that fit into chest portions 39 and 46 . The bottom section 101 of air core 24 is linear and has a length about the length of zipper 51 . Air core 28 has air impervious plastic sheet members 57 and 58 having outer peripheral edges 59 and vertical strips 76 to 87 heat sealed together forming enclosed vertical air chambers 61 to 74 , shown in FIGS. 9 and 10 . Horizontal strips 89 and 91 are heat sealed together generally parallel to the bottom edge 101 . The bottom ends of vertical strips 76 to 87 are spaced about horizontal strips 89 and 91 providing an air feeder passage 94 open to the bottom ends of air chambers 61 to 74 . The middle sections 88 of sheet member 57 and 58 are sealed together between back air chambers 61 and 67 . Strips 88 and 91 have adjacent ends spaced from each other providing a port 92 between a passage 93 and air feed passage 94 to allow air to flow into and out of air chambers 61 to 74 . The bottom of middle section 88 spaced about port 92 directs air into air feeder passage 94 .

As shown in FIGS. 1 and 12 , air pulsator 29 has a box shaped case 106 supporting an ON-OFF switch 107 for controlling the operation of a d.c. electric motor 108 . An adjustable control 109 , shown as a dial in FIG. 1 , functions to control the operating speed of motor 108 which regulates the pulse cycles or frequency of the pulses. For example, control 109 is adjustable to regulate the air pulses between 3 to 15 air pulses per second.

Pulsator 29 has a square tubular body 111 with openings 112 and 113 in opposite walls 114 and 116 . End plates 117 and 118 connected to opposite ends of body 111 close chamber 119 in body 11 and confine motor 108 to chamber 119 . Plates 117 and 118 can be provided with openings to allow air to flow through chamber 119 and motor 108 . Openings 112 and 113 are covered with head plates 121 and 122 . Head plate 121 has a generally rectangular chamber 123 . A generally square diaphragm 124 extended across chamber 123 is clamped to wall 114 with bolts 126 . A variable orifice proportional free-flow valve 128 is connected to end plate 118 to vary the pressure of air in pulsator 29 and jacket 24 . Air hose 31 is connected to end plate 117 . Hose 31 transmits air pulses from pulsator 29 to jacket 24 . The pressure of the air in pulsator 29 and jacket 24 is between 0.25 psi and 1 psi. Other air pressures can be used.

Head plate 122 has a generally rectangular chamber 129 closed with a generally rectangular diaphragm 131 . Bolts 132 clamp head plate 122 and diaphragm 131 to wall 116 . A one-way valve 134 mounted on end plate 118 allows air to be drawn into pumping chamber 119 upon operation of pulsator 29 to inflate the air core 28 in jacket 24 . Valve 134 is a reed-type or flapper-type check valve that allows air to flow into pumping chamber 119 in response to reciprocating movements of diaphragms 124 and 131 and automatically close when the flow of the air attempts to reverse direction. When the air pressure in pumping chamber 119 falls below atmospheric pressure, valve 134 allows additional air to be drawn into pumping chamber 119 . An air pump (not shown) coupled to air hose 31 can be used to supply air under pressure to jacket 24 and pulsator 29 to initially inflate apparatus 10 .

Diaphragms 124 and 131 have the same size and structure. Diaphragm 124 , shown in FIGS. 15 and 16 , has rigid top and bottom plates 136 and 137 . The plates 136 and 137 are plastic members reinforced with glass fibers. An expanded polyvinyl chloride core 138 is sandwiched between plates 136 and 137 . Core 138 is bonded to the inside surfaces of plates 136 and 137 to connect and reinforce plates 136 and 137 . A flexible flange 139 projects outwardly from the outer peripheral edges of plates 136 and 137 . Flange 139 is a rectangular flat member of air impervious flexible material, such as rubber, plastic or metal. The inner portion 141 of flange 139 is located between and secured to plates 136 and 137 . The outer portion of flange 139 has holes 142 for bolts 126 that secure head plate 121 and flange 139 to wall 114 . Flexible flange 139 allows plates 136 and 137 to be laterally moved, as shown as arrows 143 , relative to chamber 119 to pulse the air in chamber 119 .

Diaphragm 131 has the same structures as diaphragm 124 including rigid plates 144 and 146 , foam core 147 and flexible flange 148 , shown in FIG. 12 . Flexible flange 148 allows plates 144 and 146 to be laterally moved, as shown by arrows 149 , relative to chamber 119 to pulse the air in chamber I 19 .

A motion transmitting mechanism, indicated generally at 151 in FIG. 12 , drivably connected to motor 108 converts rotary motion to reciprocating motion to linearly move diaphragms 124 and 131 relative to chamber 119 . This causes the air in chamber 119 to pulse by repetitively increasing and decreasing air pressure as diaphragms 124 and 131 are forced into and out of chamber 119 . Chamber 119 can be partially filled with solid filler material (not shown) to reduce the clearance volume of chamber 119 and thereby increase the magnitude of the air pulse.

Motion transmitting mechanism 151 has a pair of circular cams 152 and 153 keyed to motor drive shaft 152 . As shown in FIGS. 12 and 14 , cams 152 and 153 eccentrically mounted on shaft 154 move cam followers 156 and 157 in opposite linear directions. Cams 152 and 153 have 180-degree eccentricity to balance the forces on cam followers 156 and 157 during rotation of shaft 154 . An ear 158 joined to cam follower 156 is pivotally connected to a yoke 159 with a pin 161 . A layer of adhesive or bonding material 162 secures yoke 159 to the center of diaphragm 124 . Cam follower 157 has an ear 163 connected to a yoke 164 with a pin 166 . Yoke 164 is secured with an adhesive or bonding material to the center of diaphragm 131 . Cam follower 156 has a rectangular opening 167 accommodating cam 152 and upper and lower faces 168 and 169 that contact cam 152 . Cam follower 157 has a rectangular opening identical to opening 167 accommodating cam 153 and upper and lower faces that contact cam 153 . Motor 108 operates to rotate cams 152 and 153 which move cam followers 156 and 157 in opposite directions thereby moving diaphragms 124 and 131 in opposite linear directions to pulse air in chamber 119 .

Cam followers 156 and 157 are located in a casing 171 having linear walls 172 and 173 that have flat guide surfaces engageable with opposite sides of cam followers 156 and 157 . Casing 171 has a center rib 174 and end plates 176 and 177 that retain cam followers 156 and 157 in casing 171 . Supports 178 and 179 mount casing 171 on walls 181 and 182 of body 111 to fix the location of casing 171 in chamber 119 .

In use, jacket 24 is placed about the person's body and retained in place with shoulder straps 36 and 37 connected to releasable members 42 and 48 . The circumferential location of jacket is maintained with connected releasable fasteners 44 and 54 , 56 . Air pulsator 29 is connected to vest air input tube 32 with an elongated flexible hose 31 .

The operation of pulsator 29 is commenced to charge the vest and pulsator 29 with air under pressure. The air inflates air core 28 . As shown in FIG. 9 , the air flows through manifold 93 , passage 92 into upright chambers 61 to 74 . The inflated air core 28 holds inside liner 27 in firm engagement with the front, back and sides of the person's body.

Switch 107 is turned ON to start motor 108 which operates the rotary to reciprocating motion transmission mechanism 151 connected to diaphragms 124 and 131 . The frequency of the air pulses is adjusted with motor speed control 109 to provide efficient and effective pulses to the person's body. Diaphragms 124 and 131 increase air pressure in chamber 119 to provide an air pulse in jacket 24 . When diaphragms 124 and 131 are moved inwardly or toward each other the air pressure in chamber 119 is increased to provide the air pressure pulse in jacket 24 . The diaphragms 124 and 131 have rigid plates connected to flexible peripheral flanges which allows linear movements of diaphragms 124 and 131 so that relatively small movements of diaphragms 124 and 131 relative to chamber 119 cause a sufficient change in air pressure in chamber 119 . This air pressure change causes repeated pressure pulses in jacket 24 . The frequency of the pulses generated in jacket 24 can be altered by changing the speed of motor 108 . Control 109 is used to change the speed of motor 108 to alter the frequency of movements of diaphragms 124 and 131 which control the frequency of the air pulses. Also, reducing the clearance volume of chamber 119 can increase the magnitude of the air pressure pulse.

The present disclosure is a preferred embodiment of the body pulsating apparatus. It is understood that the body pulsating apparatus is not to be limited to the specific materials, constructions and arrangements shown and described. It is understood that changes in parts, materials, arrangement and locations of structures may be made without departing from the invention.

Claims

1. A pulsator for generating repetitive air pressure pulses useable by a device for applying repetitive pressure pulses to a living body comprising: a body having an internal air chamber, a first diaphragm extended across the air chamber, a second diaphragm extended across the air chamber opposite the first diaphragm, fastening means connecting the first and second diaphragms to the body, a motor, a motion transmitting mechanism connecting the motor to the first and second diaphragms operable to laterally move the first and second diaphragms in only linear opposite directions relative to the air chamber to increase and decrease the pressure of the air in the air chamber thereby generating repetitive air pressure pulses, means for allowing air to flow into said air chamber, and means adapted to carry air pressure pulses from the chamber to the device for applying repetitive pulses to a living body.

2. The pulsator of claim 1 wherein: the first and second diaphragms each have rigid plate means and a flexible flange secured to the plate means, said motion transmitting mechanism being connected to the rigid plate means to laterally move the plate means, said flange being secured to the body with the fastening means.

3. The pulsator of claim 1 wherein: the first and second diaphragms each have a rigid first plate, a rigid second plate laterally spaced from the first plate, said first and second plates having outer peripheral edges, a core located between and secured to the first and second plates, and a flexible flange secured to the first and second plates, said flange extended outwardly from the outer peripheral edges of the first and second plates to allow lateral movements of the first and second plates, said flange being secured to the body with the fastening means.

4. The pulsator of claim 3 wherein: the flexible flange has a portion located between and secured to the first and second plates.

5. The pulsator of claim 1 wherein: the means for allowing air to flow to said air chamber comprises one-way valve means allowing air to flow into the air chamber in response to movement of the diaphragms and preventing air to flow from the air chamber back through the one-way valve means.

6. A pulsator of generating repetitive air pressure pulses useable by a device for applying repetitive pressure pulses to a human body comprising: a body having a first opening, a second opening, a first diaphragm extended across the first opening, a second diaphragm extended across the second opening an internal air chamber between said first and second diaphragm, fastening means connecting the first and second diaphragms to the body, a motor, a motion transmitting mechanism located within the internal air chamber connecting the motor to the first and second diaphragms operable to move the first and second diaphragms in only linear opposite lateral directions relative to the air chamber to increase and decrease the pressure of the air in the air chamber between the diaphragms thereby generating repetitive air pressure pulses, valve means for allowing air to flow into said air chamber, and means adapted to carry air pressure pulses from the chamber to the device for applying repetitive pressure pulses to a human body.

7. The pulsator of claim 6 wherein: the valve means for allowing air to flow into said air chamber comprises one-way valve means allowing air to flow into the air chamber in response to movement of the diaphragms and preventing air to flow from the air chamber back through the one-way valve means.

8. The pulsator of claim 6 wherein: the first and second diaphragms each have rigid plate means and a flexible flange secured to the plate means, said motion transmitting mechanism being connected to the rigid plate means to laterally move the plate means, said flange being secured to the body with the fastening means.

9. The pulsator of claim 6 wherein: the first and second diaphragms each have a rigid first plate, a rigid second plate laterally spaced from the first plate, said first and second plates having outer peripheral edges, a core located between and secured to the first and second plates, and a flexible flange secured to the first and second plates, said flange extended outwardly from the outer peripheral edges of the first and second plates to allow lateral movements of the first and second plates, said flange being secured to the body with the fastening means.

10. The pulsator of claim 9 wherein: the flexible flange has a portion located between and secured to the first and second plates.

11. A pulsator for generating repetitive air pressure pulses useable by a device for applying repetitive pressure pulses to a human body comprising: a body having a first opening, a second opening, and an internal air chamber between said openings, a first diaphragm extended across the first opening, a second diaphragm extended across the second opening, fastening means connecting the first and second diaphragms to the body, a motor, rotary power transmitting means connected to the motor, a motion transmitting mechanism located within said internal air chamber operatively connecting the power transmitting means to the first and second diaphragms, said motion transmitting mechanism including first and second cams eccentrically secured to the power transmitting means with the first cam eccentrically positioned 180 degrees from the second cam, a first cam follower engageable with the first cam, means connecting the first cam follower to the first diaphragm, a second cam follower engageable with the second cam, means connecting the second cam follower to the second diaphragm, guide means engageable with the first and second cam followers to limit movements of the first and second cam followers to linear reciprocating movements whereby operation of the motor rotates the first and second cams which linearly reciprocates the cam followers and laterally moves the first and second diaphragms in opposite lateral directions thereby generating repetitive air pressure pulses in said air chamber, valve means for allowing air to flow into said chamber, and means adapted to carry air pressure pulses from the chamber to the device for applying repetitive pressure pulses to a human body.

12. The pulsator of claim 11 wherein: the first and second diaphragms each have a rigid plate and a flexible flange secured to the plate, said cam followers of the motion transmitting mechanism being connected to the rigid plates to laterally move the plates in opposite directions, said flange being secured to the body with the fastening means.

13. The pulsator of claim 11 wherein: the first and second diaphragms each have a rigid first plate, a rigid second plate laterally spaced from the first plate, said first and second plates having outer peripheral edges, a core located between and secured to the first and second plates, and a flexible flange secured to the first and second plates, said flange extended outwardly from the outer peripheral edges of the first and second plates to allow lateral movements of the first and second plates, said flange being secured to the body with the fastening means.

14. The pulsator of claim 13 wherein: the flexible flange has a portion located between and secured to the first and second plates.

15. The pulsator of claim 11 wherein: the valve means for allowing air to flow into said air chamber comprises one-way valve means allowing air to flow into the air chamber in response to movement of the first and second diaphragms and preventing air to flow from the air chamber back through the one-way valve means.