DE202010010710U1 - Wall construction for a radiation protection bunker - Google Patents

Abstract

Wall construction of a radiation protection bunker (100) having a passage (10) in the interior (105) of the radiation protection bunker (100), wherein the wall construction (10) at least a first and a second wall portion (11, 12), and the first and the second Wall section (11, 12) offset from one another, wherein one of the wall sections (11, 12) to the interior (105) of the radiation protection bunker (100) is offset, the offset (13) substantially the wall thickness of one of the wall sections (11, 12) is present, and an overlap region (14) is present in which the wall sections (11, 12) overlap, wherein one of the two wall sections has a partial region (105) from a first, the passage closing position (A) in a second , the passage releasing position (B) is movable, wherein the movement along the overlap region (14) takes place, and the partial region (15) has a narrow side (23) in the first position (A) to ei NEN corresponding portion (24) of the portion (15) having wall portion (11, 12) is present.

Description

The The invention relates to a wall construction for a radiation protection bunker and a radiation protection bunker having the wall construction.

at Radiation protection bunkers are radiation shielding rooms, in particular as Linear accelerator bunker, for the medical radiotherapy. A possible embodiment of such systems is a radiation protection bunker with a so-called labyrinth guide. In this embodiment The entrance area is through an additional lock wall both from the primary as well as from the secondary radiation kept free. As final Radiation protection is the lock area over a door from the area outside of the radiation protection bunker separately. A disadvantage of such Construction is the high space requirement for the lock area, the also completely must be surrounded with radiation protection material, resulting in high construction costs arise because corresponding radiation-shielding material costly is.

Known are radiation protection sliding gates with heavy concrete filling for labyrinthless linear accelerators known. Through these sliding gates it is possible to radiation protection bunker to run labyrinthless, because due to the gate an equivalent Strahlungsabsorbtionswirkung is achieved, as this is possible with the labyrinth bunkers. The radiation protection bunker has a radiation protection wall, before the radiation protection gate can be moved on guide rails. A disadvantage of this construction is that for the patient a so-called Tunnel effect occurs when moving through the passage area should go to the radiation protection bunker. This arises as a result, that he not only has to go through the wall as such, but that he has the wall thickness must cross the gate, making for many patients an intimidating and scary Effect occurs. Furthermore, it is in such Torkonstruktionen the outside the wall is usual, that the gates overlaps across from have the passage opening, to ensure adequate radiation protection. Usually there are overlaps on both sides of 15 cm usual. The disadvantage here is that these overlapping areas when moving of the gate have to be moved, what a normal radiation protection door made of radiation protection concrete two to four tons of additional weight can make up.

Farther is disadvantageous in such a construction that these overlapping areas have to be moved before ever a release of the passage can take place. This causes a Time Delay, due to the frequent opening and Shut down of the gate for every single patient and the operating staff a relevant Time component over the day or the year, resulting in the time of use of the medical facilities located within the radiation protection bunker is reduced.

When Another disadvantage of radiation protection gates, the outside the bunker construction overlapping run an increase in the Cubature of the building, which also increased with Costs associated.

Of the Invention is therefore the object of the aforementioned problem in terms of opening hours, Weight and cubature and associated increase in the service life and reduction of To improve construction costs.

When solution for the Task proposes The invention relates to a wall construction of a radiation protection bunker with a passage into the interior of the radiation protection bunker, wherein the wall construction at least a first and a second wall portion and the first and second wall sections offset from one another are arranged, wherein one of the wall sections to the interior of the Radiation protection bunker is offset, the offset substantially the wall thickness one of the wall sections corresponds, and an overlap area exists is, in which the wall sections overlap, wherein one of the two wall sections has a partial area of a first, closing the passage Position in a second, the passage releasing position movable is moving along the overlap area, and the portion has a narrow side which in the first Position to a corresponding area of the subarea having wall portion abuts.

Advantageous It is that by integrating the passage in the wall section and the provision of an opening and closing Function within the wall section on the one hand the cubature of the Bunkers is reduced, still no overlap areas like them are provided in door systems, are provided so that the opening and Shutter speeds are reduced, and at the same time the gate masses be reduced, which on the one hand the operating times of the technical equipment (three more patients per day and more) increased and on the other material costs saves. Furthermore, by integrating the passage occlusive Area in the wall construction of the tunnel effect greatly reduced.

A further teaching of the invention provides that the wall thickness of the wall section offset from the interior of the radiation protection bunker Overlap area is performed diagonally decreasing. Particularly preferably, the wall thickness of the offset to the interior of the radiation protection bunk wall portion on the technically possible smallest wall thickness. Furthermore, it is preferred that the angle of the diagonal is selected such that the wall thickness of the wall section offset relative to the interior of the radiation protection bunker has the required nominal thickness at the end of the overlapping area. The advantage here is that is further reduced by the provision of the diagonal portion of the tunnel effect in the passage area without the radiation protection capability of this area decreases.

A Another teaching of the invention provides that the offset a parallel offset is. This causes the two wall sections parallel to each other are arranged and in this way the one possible simple construction of the wall construction is made possible.

A Another teaching of the invention provides that of the sub-area having wall portion a fall above the portion having. In this way, the size of the passage can be minimized necessary degree reduced which simultaneously reduces the masses to be moved of the movable portion causes. At the same time, the radiation protection effect to be kept.

A Another teaching of the invention provides that the narrow side of the Partial area in the second position with the beginning of the overlapping area in the Essentially aligned. Also this way ensures that no unnecessary movements the gate masses and thus no unnecessary movement time necessary are. At the same time, the radiation absorbing ability becomes maintained.

A Another teaching of the invention provides that the sub-area and the associated wall section the same wall thickness exhibit. It is also advantageous that the sub-area and the wall sections are made of the same material, preferably made of radiation protection concrete and / or barite concrete, and / or the same absorbability exhibit. This will make it possible, too with constant absorption effect with respect to the radiation to reduce cubature and consistent radiation absorption capabilities to ensure.

Regarding of the radiation protection bunker, the invention provides that this one Wall construction of the type described above and has a daylight opening, so in the shell of the radiation protection bunker is arranged that the light emission in the Area of the releasable through the subsection passage is made. The provision of such a daylight opening allows the access area for the Make patients more friendly, so also a reduction possibly existing unpleasant feelings on the patient side causes becomes. At the same time it is possible provide cost-saving daylight. This effect is additionally improved if preferred, the light output in the area above the through Subarea of releasable passage is made. Furthermore, it is preferable that the daylight opening is provided by a light well, preferably with glass elements is separated from the environment. Advantageously, the surface makes the Daylight opening in about 1/6 or more of the interior bunker area.

following The invention is based on an embodiment in connection closer with a drawing explained. Showing:

1 a first sectional view of a radiation protection bunker according to the invention in side view,

2 a second sectional view of a radiation protection bunker according to the invention in side view,

3 a sectional view through a radiation protection bunker according to the invention in plan view, and

4 an enlarged view of a wall section according to the invention according to 3 ,

An inventive radiation protection bunker 100 has a treatment room 105 in which a linear accelerator 110 is arranged. The radiation protection bunker is formed by a sole 130 , Walls 140 . 141 . 142 and 143 which act as both exterior and interior walls. Above is a blanket 135 arranged in a roof 115 passes. The walls 140 . 141 . 143 can be exterior walls. In the current embodiment of the radiation protection bunker 100 are two treatment rooms 105 provided by a wall 142 are separated. Furthermore, a wall construction 10 provided, which forms the fourth wall. This wall construction is intended for one treatment room each.

The linear accelerator 110 releases radiation for treatment purposes. This radiation comes from an isocenter 150 out. The in the direct area of the radiation, starting from the isocenter 150 lying wall sections are as reinforced wall areas 144 . 145 . 146 and as a reinforced ceiling area 136 executed.

In the ceiling 135 is a light shaft 120 provided, the glass as a separation 121 has and a cover 122 , That through the light shaft 120 incident light illuminates a light space 17 who is in the treatment room 105 behind the wall construction 10 is located and a passage 101 , the part of the wall construction 10 is lit up. The natural incidence of light saves costs for the lighting and creates a friendly atmosphere for the patients. The construction of the bunker is in 1 to 3 shown.

The wall construction 10 is in 3 and enlarged in 4 shown. The wall construction 10 consists of a first wall section 11 and a second wall section 12 , The second wall section 12 is opposite the first wall section 11 offset in parallel in the treatment room 105 arranged in it. This parallel offset is considered an offset 13 in 3 and 4 shown. The first wall section 11 and that around the offset 13 offset second wall section 12 have an overlap area 14 on. In the overlap area 14 the second one points inwards into the treatment room 105 in offset wall section 12 a beveled area 16 on. Through the beveled area 16 becomes an opening of the passage 101 causes so-called tunnel effect as it passes through the passage for the patient is reduced or avoided. At the same time, the radiation absorption line of the wall portion becomes 10 guaranteed in the overlap area. The wall construction 10 indicates the passage 101 on, by which the patients and coworkers the treatment room 105 to enter. In the area of the passage 101 is in the first wall section 11 a subarea 15 provided, which acts as a door leaf. The gate leaf 15 is between a first position A and a second position B in the direction of movement 10 parallel to the overlap area 14 movable. The first position A represents the closed position of the passage 101 whereas the second position B is in the open position of the passage 101 represents. The gate leaf 15 is for example via rollers (not shown) on rails (not shown) movable and is driven by a drive (not shown), for example, an electric motor with gearbox driven.

Above the subarea 15 is a fall 18 arranged in the area of the transition to the ceiling 135 a bevel 19 has (see 1 and 2 ).

The subarea 15 has a narrow side 23 on, at the contact strips 20 are arranged. The wall section 11 also has a narrow side in the corresponding area 24 on, the wells 25 has for receiving the contact strips 20 , In the narrow side 24 of the first wall section 11 are sensors 21 intended. About the contact strips 20 and the sensors 21 It monitors the opening and closing of the door while ensuring that no one is in the doorway when closing the door 101 is squeezed.

The narrow side 23 of the door leaf 15 closes flush with the narrow side 24 the wall of the first wall section 11 , In the area of the contact area between the narrow sides 23 and 24 and in the transition between door leaf 15 and fall 18 is a gap cover 22 which ensures that radiation protection is provided in these transitional areas.

Due to the fact that a flush closing the door leaf 15 within the first wall section 11 in the closed position A, an additional overlap area, which is 15 cm in conventional gates, which in the provision of barite concrete has a weight of two to four tons depending on the door height, can be dispensed with. As a result, the gate can be made easier, it can be a lower drive power can be provided, and the gate can be moved faster, which overall cost savings through less material, smaller technology can be achieved and at the same time faster opening and closing of the door leaf 15 ensuring that one or more patients can be treated more each day.

The wall sections 11 . 12 and the reinforced wall areas 144 . 145 . 146 are preferably carried out in baryte concrete, which has an improved radiation absorption line. Other materials are conceivable here, as long as the sufficient Stahlungsabsorbtionswirkung is guaranteed.

10

wall construction

11

first wall section

12

second wall section

13

offset

14

overlap area

15

Portion / door leaf

16

bevel

17

clearance

18

fall

19

bevel

20

contact strip

21

sensor

22

gap cover

23

narrow page

24

narrow page

25

admission

100

Radiation Bunker

101

passage

105

treatment room

110

linear accelerator

115

top, roof

120

light well

121

Glass

122

cover

130

sole

135

blanket

136

Reinforced ceiling area

140

wall

141

wall

142

wall

143

wall

144

reinforced wall area

145

reinforced wall area

146

reinforced wall area

150

isocenter

Claims (10)

Wall construction of a radiation protection bunker ( 100 ) with a passage ( 10 ) in the interior ( 105 ) of the radiation protection bunker ( 100 ), whereby the wall construction ( 10 ) at least a first and a second wall portion ( 11 . 12 ), and the first and second wall sections ( 11 . 12 ) are arranged offset to one another, wherein one of the wall sections ( 11 . 12 ) to the interior ( 105 ) of the radiation protection bunker ( 100 ), the offset ( 13 ) substantially the wall thickness of one of the wall sections ( 11 . 12 ) and an overlap area ( 14 ) is present, in which the wall sections ( 11 . 12 ), wherein one of the two wall sections forms a subregion ( 105 ) movable from a first, passage-closing position (A) to a second passage-releasing position (B), said moving along the overlapping area (FIG. 14 ), and the subarea ( 15 ) a narrow side ( 23 ) in the first position (A) to a corresponding area ( 24 ) of the subarea ( 15 ) having wall section ( 11 . 12 ) is present. Wall construction according to claim 1, characterized in that the wall thickness of the interior ( 105 ) of the radiation protection bunker ( 100 ) offset wall section ( 11 . 12 ) in the overlapping area ( 14 ) is performed diagonally decreasing. Wall construction according to claim 1 or 2, characterized in that the offset ( 13 ) is a parallel offset. Wall construction according to one of claims 1 to 3, characterized in that the subregion ( 15 ) having wall section ( 11 . 12 ) a fall ( 18 ) above the subarea ( 15 ) having. Wall construction according to one of claims 1 to 4, characterized in that the narrow side ( 23 ) of the subarea ( 15 ) in the second position (B) with the beginning of the overlapping area ( 14 ) is substantially aligned. Wall construction according to one of claims 1 to 5, characterized in that the partial area ( 15 ) and the associated wall section ( 11 . 12 ) have the same wall thickness. Wall construction according to one of claims 1 to 6, characterized in that the partial area ( 15 ) and the wall sections ( 11 . 12 ) are made of the same material, preferably of radiation protection concrete and / or baryta concrete, and / or having the same Strahlabsabsobtionsfähigkeit. Radiation protection bunker with a wall construction according to one of claims 1 to 7 and a daylight opening ( 120 ), which in the shell of the radiation protection bunker ( 100 ) is arranged so that the light output in the area ( 17 ) of the subregion ( 15 ) shared passage ( 101 ) he follows. Radiation protection bunker according to claim 8, characterized in that the light output in the area ( 17 ) above the area ( 15 ) releasable passage ( 101 ) he follows. Radiation protection bunker according to claim 8 or 9, characterized in that the daylight opening a light shaft ( 120 ) and / or that the area of the daylight opening constitutes substantially 1/6 or more of the interior surface of the bunker.