GR1010808B - Manually operated spinal decompression mechanism - Google Patents

Abstract

Manual traction-based spinal decompression mechanism combined with long hours of bed rest, especially at bedtime. It consists of the adjustable base A 5 (fig. 1) which secures via the security bar 3 the two ends of which pass behind the two legs of the bed and of the base B (fig. 2) which secures on the opposite side of the wall, when there is no space to place the security bar behind the two legs of the bed. Both bases A (fig. 1) and B (fig. 2) are foldable and provided with hinges and rotating shafts to secure. Said bases bear on the top a traction regulator to which traction-creating resistance elastics are connected. These elastics are connected by straps held at four points by the belt. The patient places the belt a little below the waist of the body (on the hip), gets on the bed, connects the elastics to the traction regulator, sets the traction strength desired, moves to the back of the bed, wears the two underarm holders to stabilize his body, removes the invented mechanism from his body without getting up and sleeps. The invention is used by the patent before bedtime, in his bed, for forty to fifty minutes (essential treatment is lasting while sleeping).

Description

DESCRIPTION

MANUAL VERTEBRA DECOMPRESSION MECHANISM

The invention refers to a manual mechanism for decompression and rejuvenation of the vertebrae based on traction using resistance bands, combined with long hours of rest, especially at bedtime. It consists of a belt that we tie just below the waist on the hip and that is equipped with straps and traction bands, which when climbing into bed we connect to the traction regulator of the base which is placed externally at the bottom of the bed. Then we move to the top of the bed, the bands stretch and a specific traction force is created, depending on the adjustment we have made and depending on the resistance of each band that we will choose and we place the two armrests to stabilize the body. We remain in this position for about forty minutes, remove the belt and the armrests without getting out of bed and go to sleep. Thus, throughout sleep, the vertebrae remain open and revitalized. In this way, recovery is quick and effective.

There are many traction systems for decompression of the vertebrae and they are well known. The treatment of vertebral decompression is applied by visiting professional facilities that have these machines. After the treatment, the patient gets up and leaves walking. This results in the vertebrae being compressed again, by the weight of the body, and returning to their original position. For this reason, many such treatments are needed, at a very high cost and in parallel with the duration of time, for the patient to see some not significant result. There are other traction systems that the patient uses alone at home. But these also have the same effect because the patient will stand up again after use, and the vertebrae will be compressed again. This is because it is not known that the patient should not get out of bed for many hours after traction.

The advantage of this invention is that this specific treatment is performed with a manual mechanism by the patient himself at night, before and during sleep in his bed, with a controlled, but also partially variable traction force, when we move towards the top of the bed or towards the bottom, because the traction is done with resistance bands, which are connected to one of the many points of the traction regulator, for greater or lesser traction force. To stabilize the body, we wear both armpits. After about forty to fifty minutes, the patient, without getting out of bed, unfastens the traction belt from his body, which by itself moves to the bottom of the bed, from the traction bands, removes the armpits and sleeps. Thus, the vertebrae, once decompressed, are not compressed after the treatment, they remain relaxed and open during sleep, resulting in being revitalized and reorganized for many hours, in a safe and natural way. In this way, the essential treatment takes place for many hours at night, while we sleep, and this results in a very rapid recovery from spinal problems.

The specific manual vertebral decompression mechanism, according to the present invention, has the particularity that the patient himself can use it at home, in an easy and relaxed manner, to increase or decrease the force of the decompression traction and after the treatment to remove the mechanism from his body without having to get out of bed, until the next morning. In this way, the treatment after the decompression lasts all night and during sleep the vertebrae remain open, as a result of which the spaces between the vertebrae increase, the cavities are significantly reduced and the treatment is easily achieved in a relaxed manner, at minimal cost and in much less time.

According to the invention, the traction force is adjusted by changing the connection point on the traction regulator, with the rubber bands, and by selecting the resistance force that each rubber band we will use has.

Figure 1 shows the base A1 with the resistance lever, the safety bar placed in the base socket and the two extreme points of the bar passing behind two legs of the bed. At the top of the base is the traction regulator with the belt of straps and the resistance rubbers that connect the body to the traction regulator. A strap is connected to the headboard of the bed which holds the two armrests, which are placed with a strap around the headboard of the bed at the top and which hold the body steady. A third strap secures and connects the traction regulator to a strap on the bar.

Figure 2 shows the A2 base, which can also be used for a bed without legs. It consists of two bars, placed outside the bed at the top and bottom, connected to each other around the perimeter with a strap, a second strap connects the large bar to the two legs of the bed at the bottom. The resistance lever with the traction regulator is connected to the bar. A third strap secures and connects the traction regulator to a strap on the bar.

A simple way of implementing the invention is described with reference to the drawings, of base A1 (fig. 1) and base A2 (fig. 2) which are made of wood and their parts are connected by metal hinges and metal fittings.

The base A1 (fig.1) consists of the lower surface plate (1), which is in contact with the floor. On the plate is placed the socket (2) of the safety bar, in which the safety bar (3) is placed, which is fixed behind the two legs of the bed. The rotating shaft (4) for moving the resistance lever until the resistance lever (5) touches the bed, in order to fix the base. The traction regulator (6). The movable traction pin (7). The daisy screw (8) for connecting the traction regulator. The traction belt (9), to which straps are connected at four points, (10) two at the front of the body and two at the back. The straps (10) are connected to the traction rubbers (11), which are connected to the traction regulator. On the headboard of the bed, the strap with the two armrests (12) which hold the body stable.

When the bed does not have legs, we use the base (A2) (fig.2), which consists of a large bar (1), which is placed at the bottom of the bed, a smaller bar (2) placed at the top of the bed, a strap with a tie (3), which connects the two bars around the perimeter of the bed, a second strap that connects the large bar to the lower legs of the bed by the resistance lever (4) which is connected to the daisy screw (5) on the large bar, and the traction regulator (6) which is connected to the resistance lever. The strap on the headboard of the bed with the two armrests (7). The bases A and B are connected to the traction belt, which is tied to the patient's body just below the waist at the hip and consists of the belt (8), which is connected in four movable positions on the belt with straps two at the front of the body and two at the back of the body (9). The straps are connected to a resistance band (10) with a total circumference of 208 cm, which folds at the waist and thus the length becomes 104 cm and is connected to the traction regulator at two points. Thus, when the patient climbs into the bed and moves to the upper part, the bands that stretch are four and the traction force increases with the corresponding elongation, which is determined by the traction regulator and by the point of the body. To stabilize our body we wear both armpits. For every 10 cm of elongation, the traction force increases by 10 kg. So the maximum pulling force is about 40 kg. To create more pulling force we use a harder resistance band.

According to the invention, the patient can place and remove the resistance base externally on the bottom of the bed by himself. The resistance base does not interfere with the functionality of the room and the bed, because the traction regulator, after use, unlocks and descends vertically towards the resistance lever. He can also easily place and remove from his body the traction belt with the straps and rubber bands used for traction, as well as the armpits.

Claims (4)

1. The manual vertebral decompression mechanism in combination with long-term bed rest, especially during sleep, without the patient getting out of bed. The mechanism includes the base A (fig.1), the base B (fig.2) which are connected to the traction belt and the strap on the headboard of the bed with the two armrests that hold the body firmly. The base A (fig.1) is placed externally at the bottom of the bed and the bottom of the base passes under the bed. The base A (fig.1) consists of the lower surface plate (1) on which the safety bar holder (2) is placed, the safety bar (3) which is placed in the base holder and its two ends pass behind the two legs of the bed at the bottom to secure and prevent the base from moving. The rotating shaft (4) for moving the resistance lever (5) until the resistance lever touches the bed. The traction regulator (6) with the movable adjustment pin (7), which increases or decreases the traction force. And the butterfly screw (8), which connects the resistance lever to the traction regulator. The strap (8) which creates an additional safety valve because it connects the traction regulator to a strap on the bar. The traction belt (9) which is connected to straps (10) and the resistance bands (11) which are connected to the straps. The belt with the two armrests (9) which are on the headboard of the bed and stabilize the body. 2. The base B, which is also suitable for beds without a skirt, (fig.2) consists of the large bar (1) which is placed at the bottom of the bed, the small bar (2) which is placed at the top of the bed, the strap with the tie (3) which connects the two bars, the resistance lever (4) which is connected to the large bar, the traction regulator (5) which is connected to the resistance lever. Strap (6) for an additional safety valve which connects the traction regulator to a strap below the bar. The traction belt consists of the waist belt (7), the belt connection straps (8) and the resistance rubbers (9). The strap with the two armrests (10) on the headboard of the bed To apply, the patient places the base A (fig.1) or B (fig.2) at the bottom of the bed, depending on the type of bed, connects the traction regulator and adjusts the traction force. Then he puts on the traction belt, with the straps and the resistance bands, climbs into bed, connects the resistance bands to the traction regulator, moves to the back of the bed and creates the traction, and puts on the two armrests to stabilize the body. 3. A necessary condition after using the system for approximately forty to fifty minutes is that the patient must remove the traction belt from his body, both armpits without getting out of bed and then go to sleep. This way the vertebrae remain open and are revitalized during sleep. 4. The manual spinal decompression device is characterized according to claims 1 and 2, in that the adjustable resistance base can be made of various materials, such as wood, metal or plastic and in various ways. The force of the traction is determined by the traction regulator, by the resistance rubber that we will use, soft, medium, or hard and by the elongation of the rubber.