Patent Publication Number: US-7708169-B1

Title: Compact powered caulking gun with scissor type dispensing mechanism

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
   Not Applicable 
   STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT 
   Not Applicable 
   REFERENCE TO SEQUENCE LISTING, A TABLE, OR A COMPUTER PROGRAM LISTING COMPACT DISK APPENDIX 
   Not Applicable 
   BACKGROUND OF THE INVENTION 
   The present invention relates to motor driven caulking gun and the like for dispensing caulk, adhesive and other viscous materials. 
   There have been attempts in the past to invent a compact motor driven caulking gun that does not have a plunger rod protruding at the back of the motor driven caulking gun. Examples of such caulking guns are shown in U.S. Pat. No. 5,503,307, invented by Steven J. Wilson and John H. Klock; and U.S. Pat. No. 6,321,945, invented by Gaston Girouard and Elinor Girouard; and U.S. Pat. Application No. US 2002/0108971 A1, invented by Luc Lafond. Unfortunately, all these inventions have their inherent impractical drawbacks. Additionally each of the aforementioned patents possesses a bulky handle, which sometimes can be in the way when applying caulk in tight spaces. 
   BRIEF SUMMARY OF THE INVENTION 
   It is an object of the present invention to provide a relatively compact caulking gun that can be easily manipulated with only one hand if required while dispensing caulk, adhesive and other viscous materials. 
   The preferred embodiments of the compact powered caulking gun comprises of a body consisting of two clamshells, with a plurality of electrical contacts incorporated into one of the clamshells. A removable cartridge cradle with a three position, rheostatic extrusion speed regulator, Forward-On, Off, Reverse-On switch attached to the body. The removable cartridge cradle having a plurality of embedded electrical terminals connected to a plurality of insulated electrical wires embedded and connected to the three position, rheostatic extrusion speed regulator, Forward-On, Off, Reverse-On switch. A motor electrically connected via the electrical contacts to the three position, rheostatic extrusion speed regulator, Forward-On, Off, Reverse-On switch. A battery electrically connected via the electrical contacts to the three position, rheostatic extrusion speed regulator, Forward-On, Off, Reverse-On switch. Two Cut-Off switches are electrically connected via the electrical contacts to the three position, rheostatic extrusion speed regulator, Forward-On, Off, Reverse-On switch. The motor operatively coupled to an actuator shaft with two oppositely pitched threads thereon. An upper link member actuator with a pitched thread formed therewithin, rotatably situated on the actuator shaft. A lower link member actuator with a pitched thread formed therewithin, rotatably situated on the actuator shaft. A scissor-type mechanism, with a pusher plate, operatively connected to the upper link member actuator and operatively connected to the lower link member actuator. 
   An optional attachable, detachable rear handle and an optional attachable, detachable gun-type handle are provided to the operator if so desired. 

   
     BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING 
       FIG. 1  is a front perspective view of the compact powered caulking gun. 
       FIG. 2  is a rear perspective view of the compact powered caulking gun. 
       FIG. 3  is a side elevation view of the compact powered caulking gun. 
       FIG. 4  is a plan view of the compact powered caulking gun. 
       FIG. 5  is a front elevation view of the compact powered caulking gun. 
       FIG. 6  is a rear elevation view of the compact powered caulking gun. 
       FIG. 7  is a front elevation view of the compact powered caulking gun with the optional rear handle attached. 
       FIG. 8  is a rear elevation view of the compact powered caulking gun with the optional rear handle attached. 
       FIG. 9  is a front perspective view of the compact powered caulking gun with the optional rear handle attached. 
       FIG. 10  is a rear perspective view of the compact powered caulking gun with the optional rear handle attached. 
       FIG. 11  is a side elevation view of the compact powered caulking gun with the optional rear handle attached. 
       FIG. 12  is a plan view of the compact powered caulking gun with the optional rear handle attached. 
       FIG. 13  is a front perspective view of the compact powered caulking gun with the optional gun-type handle attached. 
       FIG. 14  is a rear perspective view of the compact powered caulking gun with the optional gun-type handle attached. 
       FIG. 15  is a side elevation view of the compact powered caulking gun with the optional gun-type handle attached. 
       FIG. 16  is a rear elevation view of the compact powered caulking gun with the optional gun-type handle attached. 
       FIG. 17  is a front elevation view of the compact powered caulking gun with the optional gun-type handle attached. 
       FIG. 18  is an exploded view of the compact powered caulking gun. 
       FIG. 19  is a front perspective view of the scissor-type mechanism in the retracted position. 
       FIG. 20  is another front perspective view of the scissor-type mechanism in the retracted position. 
       FIG. 21  is a front perspective view of the scissor-type mechanism in the extended position. 
       FIG. 22  is a side elevation view of the actuator shaft. 
       FIG. 23  is a rear perspective view of the pusher plate. 
       FIG. 24  is a front perspective view of the upper link member actuator. 
       FIG. 25  is a front perspective view of the lower link member actuator. 
       FIG. 26  is a perspective view of the link members. 
       FIG. 27  is a rear perspective view of the left clamshell of the compact powered caulking gun body. 
       FIG. 28  is another rear perspective view of the left clamshell of the compact powered caulking gun body. 
       FIG. 29  is a front perspective view of the left clamshell of the compact powered caulking gun body. 
       FIG. 30  is a side elevation view of the left clamshell of the compact powered caulking gun body. 
       FIG. 31  is a rear perspective view of the right clamshell of the compact powered caulking gun body. 
       FIG. 32  is a front perspective view of the right clamshell of the compact powered caulking gun body. 
       FIG. 33  is another rear perspective view of the right clamshell of the compact powered caulking gun body. 
       FIG. 34  is a side elevation view of the right clamshell of the compact powered caulking gun body. 
       FIG. 35  is a plan view of the cartridge cradle. 
       FIG. 36  is a rear perspective view of the right clamshell of the compact powered caulking gun body with the battery removed. 
       FIG. 37  is a plan view of the right clamshell of the compact powered caulking gun body. 
       FIG. 38  is a rear cross sectional view of the right clamshell of the compact powered caulking gun body taken on line  110 - 110  of  FIG. 37 . 
       FIG. 39  is a rear elevation view of the cartridge cradle. 
       FIG. 40  is a front cross sectional view of the cartridge cradle taken on line  100 - 100  of  FIG. 35 . 
       FIG. 41  is a rear perspective view of the compact powered caulking gun with the right clamshell removed showing the scissor-type mechanism. 
       FIG. 42  is a rear perspective view of the compact powered caulking gun with the left clamshell removed showing the scissor-type mechanism. 
       FIG. 43  is a plan view of the compact powered caulking gun with the left clamshell removed. 
       FIG. 44  is a cross sectional view taken on line  130 - 130  of  FIG. 43 , of the compact powered caulking gun with the left clamshell removed and showing the scissor-type mechanism in the retracted position. 
       FIG. 45  is a cross sectional view taken on line  130 - 130  of  FIG. 43 , of the compact powered caulking gun with the left clamshell removed and showing the scissor-type mechanism in the extended position. 
       FIG. 46  is a front perspective view of the optional rear handle. 
       FIG. 47  is a side elevation view of the optional rear handle. 
       FIG. 48  is a side elevation view of the optional rear handle in the unfolded position. 
       FIG. 49  is a perspective view of the optional rear handle in the unfolded position with the securing buttons separated. 
       FIG. 50  is a rear perspective view of the securing button of the optional rear handle. 
       FIG. 51  is a fragmentary side elevation view of the securing button in the depressed position of the optional rear handle. 
       FIG. 52  is a front perspective view of the optional gun-type handle. 
       FIG. 53  is a side elevation view of the optional gun-type handle. 
       FIG. 54  is a side elevation view of the optional gun-type handle in the unfolded position. 
       FIG. 55  is a front perspective view of the optional gun-type handle in the unfolded position with the securing button separated. 
       FIG. 56  is a fragmentary side elevation view of the optional gun-type handle in the unfolded position with the securing button in the depressed position. 
   

   DETAILED DESCRIPTION OF THE INVENTION 
   A compact powered caulking gun ( 1 ) (shown in  FIG. 1-18 ), having a body ( 4 ), made of two clamshells ( 4   a ,  4   b ) (as shown in  FIG. 27-34 ), secured to each other through the openings ( 80   a ,  80   b ) of clamshells ( 4   a ,  4   b ) respectively, via screws ( 20 ) (shown in  FIG. 18 ). A cartridge cradle ( 2 ) is removably attached to the body ( 4 ) via openings ( 11 ,  12 ). An optional attachable, detachable rear handle ( 13 ) (shown in  FIG. 7-12 ,  46 - 51 ) can be securely attached onto the rear of clamshells ( 4   a ,  4   b ) of body ( 4 ). An optional attachable, detachable gun-type handle ( 17 ) (shown in  FIG. 13-17 ,  52 - 56 ) can be securely attached onto the rear of clamshells ( 4   a ,  4   b ) of body ( 4 ). 
   The motor ( 35 ) (shown in  FIG. 18 ,  41 ,  42 ) is securely encased in recess ( 91   a ) (shown in  FIG. 27-30 ) formed into clamshell ( 4   a ) of body ( 4 ). The motor ( 35 ) is further secured in place with supports ( 91   b ,  91   c ) formed onto clamshell ( 4   b ) of body ( 4 ) (shown in  FIG. 31-34 ,  42 - 45 ). The motor ( 35 ) can be electric and powered by rechargeable battery ( 5 ). The battery compartment ( 5   a ) (shown in  FIG. 36 ) formed into clamshell ( 4   b ) of body ( 4 ), could be designed to not only accommodate the rechargeable battery ( 5 ), but also a plurality of one time use regular AA batteries (not shown) or the like. The motor ( 35 ) is connected to a rotatable drive shaft ( 37 ) with gear ( 36 ) formed thereon (shown in  FIG. 42 ). The drive shaft ( 37 ), the gear ( 36 ) are rotatably situated in recesses ( 92   a ,  93 ,  94   a ) respectively, formed into clamshell ( 4   a ). The drive shaft ( 37 ) is further rotatably secured in place with supports ( 92   b ,  94   b ) formed onto clamshell ( 4   b ) of body ( 4 ) (shown in  FIG. 31-34 ). The gear ( 36 ) of drive shaft ( 37 ) is rotatably and meshingly coupled to transfer gear ( 32 ) (shown in  FIG. 42 ). The transfer gear ( 32 ) has an end-shaft ( 34 ) formed on one side, and a smaller transfer gear ( 31 ) with an end-shaft ( 33 ) formed on the other side (shown in  FIG. 42 ). The end-shaft ( 34 ), the transfer gear ( 32 ), the small transfer gear ( 31 ), and the end-shaft ( 33 ), are rotatably situated in recesses ( 86   a ,  87 ,  88   a ,  88   b ,  89   a ) respectively, formed into clamshells ( 4   a ,  4   b ) respectively. The end-shaft ( 33 ), and the end-shaft ( 34 ), are further rotatably secured in place with supports ( 86   b ,  89   b ) formed onto clamshell ( 4   b ) of body ( 4 ) (shown in  FIG. 31-34 ). The transfer gear ( 32 ), and the small transfer gear ( 31 ), are rotatably and meshingly coupled to the gear ( 30 ) of actuator shaft ( 25 ) (shown in  FIG. 42 ). The upper end-shaft ( 26 ) and lower end-shaft ( 27 ) of actuator shaft ( 25 ) attached to gear ( 30 ) are rotatably situated in recesses ( 81   a ,  81   b ,  83   a ,  83   b ,  82   a ,  82   b ,  84   a ,  84   b ) respectively, formed into clamshells ( 4   a ,  4   b ) respectively. 
   The actuator shaft ( 25 ) has two oppositely pitched threads ( 25   a ,  25   b ) formed thereon (shown in  FIG. 22 ). The upper thread ( 25   a ) is rotatably coupled to the upper link member actuator ( 28 ) which has a matching pitched thread ( 28   a ) formed therein (shown in  FIG. 18-21 ,  24 ). The lower thread ( 25   b ) is rotatably coupled to the lower link member actuator ( 29 ) which has a matching pitched thread ( 29   a ) formed therein (shown in  FIG. 18-21 ,  25 ). The upper link member actuator ( 28 ) has two protruding arms ( 60   a ,  60   b ) formed thereon (shown in  FIG. 24 ). Each of the arms ( 602 ,  60   b ) has an opening ( 702 ,  70   b ) formed therein respectively. The lower link member actuator ( 29 ) has two protruding arms ( 61   a ,  61   b ) formed thereon (shown in  FIG. 25 ). Each of the arms ( 61   a ,  61   b ) has an opening ( 71   a ,  71   b ) formed therein respectively. The scissor type mechanism ( 24 ) (shown in  FIG. 18-21 ,  41 - 45 ) is made of a plurality of link members ( 63   a ,  63   b ) and two short link members ( 65   a ,  65   b ) (shown in  FIG. 19-21 ,  26 ) pivotally secured to each other via rivets ( 68 ) through openings ( 72   a ,  72   b ,  73   a ,  73   b ) formed into link members ( 63   a ,  63   b ) and through openings ( 75   a ,  75   b ) formed into the two short link members ( 65   a ,  65   b ) respectively. The link member ( 63   b ) is pivotally secured to arms ( 60   a ,  60   b ) of the upper link member actuator ( 28 ) through openings ( 70   a ,  72   b ,  70   b ) with rivet ( 62 ) (shown in  FIG. 19-21 ). The link member ( 63   a ) is pivotally secured to arms ( 61   a ,  61   b ) of the lower link member actuator ( 29 ) through openings ( 71   a ,  72   a ,  71   b ) with rivet ( 62 ) (shown in  FIG. 19-21 ). The pusher plate ( 23 ) (shown in  FIG. 23 ) is attached to the two short link members ( 65   a ,  65   b ) through openings ( 69   a ,  69   b ) formed into arms ( 66   a ,  66   b ) respectively, of pusher plate ( 23 ) and through openings ( 74   a ,  74   b ) formed into the two short link members ( 65   a ,  65   b ) respectively and pivotally secured in place with rivet ( 67 ) (shown in  FIG. 19-21 ,  23 ). The scissor-type mechanism ( 24 ) in its retracted position with pusher plate ( 23 ) (shown in  FIG. 41-44 ) is situated inside recesses ( 85   a ,  85   b ,  95   a ,  95   b ) respectively (shown in  FIG. 27-34 ) formed into clamshells ( 4   a ,  4   b ) respectively. 
   The removable cartridge cradle ( 2 ) (shown in  FIG. 18 ,  35 ,  39 - 43 ) has two protruding tabs ( 22   a ,  22   b ) formed thereon. The removable cartridge cradle ( 2 ) is sized to accommodate commercially available caulk, adhesive or other viscous cartridge ( 78 ). A slot ( 6 ) is formed into the front part of cartridge cradle ( 2 ) to accommodate the nozzle ( 77 ) of a cartridge ( 78 ). The removable cartridge cradle ( 2 ) is preferably made of plastic (but composition is not limited to plastic). A three position rheostatic extrusion speed regulator, Forward-On, Off, Reverse-On switch ( 3 ) is integrally formed on the side of the removable cartridge cradle ( 2 ). As seen in  FIG. 39 ,  40 , insulated electrical wires ( 50   d ,  51   d ,  52   d ,  53   d ,  54   d ,  55   d ,  56   d ,  57   d ) are embedded in the cartridge cradle ( 2 ), that connect the electrical terminals ( 50   c ,  51   c ,  52   c ,  53   c ,  54   c ,  55   c ,  56   c ,  57   c ) embedded in tab ( 22   b ) to the rheostatic extrusion speed regulator, Forward-On, Off, Reverse-On switch ( 3 ). To securely install the cartridge cradle ( 2 ) into the body ( 4 ), the cartridge cradle ( 2 ) is positioned so that tab ( 22   a ) and tab ( 22   b ) lines up with and slides into opening ( 11 ) and opening ( 12 ) respectively. And the rear part of cartridge cradle ( 2 ) slides into recesses ( 96   a ,  96   b ) of clamshell ( 4   a ,  4   b ) respectively. Opening ( 11 ) consists of recesses ( 11   a ,  11   b ) formed into clamshell ( 4   a ,  4   b ) respectively. Opening ( 12 ) consists of recesses ( 12   a ,  12   b ) formed into clamshell ( 4   a ,  4   b ) respectively. Once tab ( 22   a ) and tab ( 22   b ) are inside opening ( 11 ) and opening ( 12 ) respectively the cartridge cradle ( 2 ) is rotated 90 degrees inside recesses ( 97   a ,  97   b ) respectively, in the direction indicated by arrow ( 99 ) in  FIG. 5 . In its secured position the electrical terminals ( 50   c ,  51   c ,  52   c ,  53   c ,  54   c ,  55   c ,  56   c ,  57   c ) of tab ( 22   b ) are electrically connected to contacts ( 50   b ,  51   b ,  52   b ,  53   b ,  54   b ,  55   b ,  56   b ,  57   b ) respectively, embedded into clamshell ( 4   b ) (shown in  FIG. 38 ). 
   The Cut-Off switches ( 44 ,  45 ) (shown in  FIG. 18 ,  41 - 45 ) are securely situated in recesses ( 46   a ,  46   b ,  47   a ,  47   b ) of clamshells ( 4   a ,  4   b ) respectively, of body ( 4 ) (shown in  FIG. 27-34 ). The Cut-Off switch ( 44 ) is electrically connected via insulated wires ( 56   a ,  57   a ) to contacts ( 56   b ,  57   b ) respectively. And the Cut-Off switch ( 45 ) is electrically connected via insulated wires ( 54   a ,  55   a ) to contacts ( 54   b ,  55   b ) respectively. The purpose of the Cut-Off switch ( 44 ) is to cut off electricity to the motor ( 35 ) when the scissor-type mechanism ( 24 ) is in its fully extended position (shown in  FIG. 45 ) to prevent any internal damage to the compact powered caulking gun ( 1 ). And the purpose of the Cut-Off switch ( 45 ) is to cut off electricity to the motor ( 35 ) when the scissor-type mechanism ( 24 ) is in its fully retracted position (shown in  FIG. 44 ) to prevent any internal damage to the compact powered caulking gun ( 1 ). The insulated electrical wires ( 50   a ,  51   a ) of motor ( 35 ) are connected to their respective contacts ( 50   b ,  51   b ). In  FIG. 41 , the insulated electrical wires ( 50   a ,  51   a ,  54   a ,  55   a ,  56   a ,  57   a ) are separated and truncated for illustration purposes, but in the actual compact powered caulking gun ( 1 ), they would be bundled together and situated in recesses ( 48   a ,  48   b ,  90 ,  98 ) of clamshells ( 4   a ,  4   b ) respectively, and further situated through opening ( 49 ) (shown in  FIG. 38 ,  31 - 34 ,  41 - 45 ) and connected to their respective contacts ( 50   b ,  51   b ,  54   b ,  55   b ,  56   b ,  57   b ) (as shown in  FIG. 38 ,  42 ,  44 ,  45 ). The insulated electrical wires ( 52   a ,  53   a ) (shown in  FIG. 36 ) of rechargeable battery ( 5 ) are connected to their respective contacts ( 52   b ,  53   b ) (shown in  FIG. 38 ). 
   To operate the compact powered caulking gun ( 1 ), the operator grasps the cartridge cradle ( 2 ), with a cartridge ( 78 ) therewithin, with one hand, and with thumb of the same hand actuates the rheostatic extrusion speed regulator, Forward-On, Off, Reverse-On switch ( 3 ) to the Forward-On direction indicated by arrow ( 3   a ). By pushing the switch ( 3 ) in the Forward-On direction, the operator activates a built in rheostatic control, which regulates the amount of voltage applied to the motor ( 35 ) from the rechargeable battery ( 5 ). The farther the operator&#39;s thumb pushes the switch ( 3 ) in the direction indicated by arrow ( 3   a ) the more voltage is applied to the motor ( 35 ) thereby increasing the extrusion speed of the material from the cartridge ( 78 ) through the nozzle ( 77 ). 
   As voltage is applied to the motor ( 35 ), it rotates the gear ( 36 ) on rotational axis ( 38 ) in the direction indicated by arrow ( 39 ) (shown in  FIG. 18 ) and creates an opposite rotational motion, indicated by arrow ( 41 ) on rotational axis ( 40 ), in transfer gears ( 32 ,  31 ) and further creates a rotational motion indicated by arrow ( 43 ) on rotational axis ( 42 ) in gear ( 30 ) thereby rotating the actuator shaft ( 25 ) and causing the upper link member actuator ( 28 ) and the lower link member actuator ( 29 ) to advance towards each other and force the scissor-type mechanism ( 24 ) to push the pusher plate ( 23 ), through opening ( 21 ) of cartridge cradle ( 2 ) (shown in  FIG. 39-42 ), towards the piston ( 79 ) of the cartridge ( 78 ) and force the piston ( 79 ) to extrude the caulk, adhesive or other viscous material from the cartridge ( 78 ) through the nozzle ( 77 ) (as shown in  FIG. 44 ,  45 ). 
   To stop the extrusion process, the operator&#39;s thumb actuates the rheostatic extrusion speed regulator, Forward-On, Off, Reverse-On switch ( 3 ) to the Off position (middle position) and cuts off electricity to the motor ( 35 ) thereby stopping the extrusion process. In order to return the scissor-type mechanism ( 24 ) to its fully retracted position (shown in  FIG. 44 ), the operator&#39;s thumb actuates the rheostatic extrusion speed regulator, Forward-On, Off, Reverse-On switch ( 3 ) to the Reverse-On position in direction indicated by arrow ( 3   b ), and holds it until the Cut-Off switch ( 45 ) is activated, thereby cutting off electricity to the motor ( 35 ) when the scissor-type mechanism ( 24 ) is fully retracted. 
   The optional attachable, detachable rear handle ( 13 ) (shown in  FIG. 7-12 ,  46 - 51 ), preferably made of plastic (but composition is not limited to plastic), formed from one piece, foldable where the two halves ( 14   a ,  14   b ) are joined at the middle ( 113 ). The two halves ( 14   a ,  14   b ) are secured to each other via a plurality of pins ( 107 ) secured into a plurality of recesses ( 108 ). Both halves ( 14   a ,  14   b ) have two guide members ( 101   a ,  101   b ,  102   a ,  102   b ) respectively, formed thereon. Opening ( 9 ) consists of recesses ( 9   a ,  9   b ) formed into clamshell ( 4   a ,  4   b ) respectively (shown in  FIG. 27-34 ). And opening ( 10 ) consists of recesses ( 10   a ,  10   b ) formed into clamshell ( 4   a ,  4   b ) respectively (shown in  FIG. 27-34 ). Recess ( 7 ) consists of recesses ( 7   a ,  7   b ) formed into clamshell ( 4   a ,  4   b ) respectively (shown in  FIG. 27-34 ). And recess ( 8 ) consists of recesses ( 8   a ,  8   b ) formed into clamshell ( 4   a ,  4   b ) respectively (shown in  FIG. 27-34 ). In the direction indicated by arrow ( 3   a ), the guide members ( 101   a ,  101   b ,  102   a ,  102   b ) slide into openings ( 9 ,  10 ) respectively and are secured into recesses ( 7 ,  8 ) by hooks ( 112 ) formed onto buttons ( 15 ,  16 ). The buttons ( 15 ,  16 ) have resilient springs ( 109 ) formed thereon, to securely engage the hooks ( 112 ) into recesses ( 7 ,  8 ), and two pivoting pins ( 111   a ,  111   b ) formed thereon. The buttons ( 15 ,  16 ) are situated in recess ( 103   a ,  103   b ,  104   a ,  104   b ) respectively, and the pins ( 111   a ,  111   b ) are pivotally situated in openings ( 105   a ,  105   b ,  106   a ,  106   b ) respectively, formed into the two halves ( 14   a ,  14   b ) respectively. If the operator desires to remove the rear handle ( 13 ), the operator with fingers pressing down on buttons ( 15 ,  16 ) (as shown in  FIG. 51 ) disengages hooks ( 112 ) from recesses ( 7 ,  8 ) and slidably removes the handle ( 13 ) in the direction indicated by arrow ( 3   b ). 
   The optional attachable, detachable gun-type handle ( 17 ) (shown in  FIG. 13-17 ,  52 - 56 ), preferably made of plastic (but composition is not limited to plastic), formed from one piece, foldable where the two halves ( 18   a ,  18   b ) are joined at the middle ( 121 ). The two halves ( 18   a ,  18   b ) are secured to each other via a plurality of pins ( 118 ) secured into a plurality of recesses ( 119 ). Both halves ( 18   a ,  18   b ) have a guide member ( 122   a ,  122   b ) respectively, formed thereon. In the direction indicated by arrow ( 3   a ), the guide members ( 122   a ,  122   b ) slide into opening ( 10 ) and are secured into recess ( 8 ) by hook ( 116 ) formed onto button ( 19 ). The button ( 19 ) has a resilient spring ( 115 ) formed thereon, to securely engage the hook ( 116 ) into recess ( 8 ), and two pivoting pins ( 114   a ,  114   b ) formed thereon. The button ( 19 ) is situated in recesses ( 117   a ,  117   b ), and the pins ( 114   a ,  114   b ) are pivotally situated in openings ( 120   a ,  120   b ) formed into the two halves ( 18   a ,  18   b ) respectively. If the operator desires to remove the gun-type handle ( 17 ), the operator with finger pressing down on button ( 19 ) (as shown in  FIG. 56 ) disengages hook ( 116 ) from recess ( 8 ) and slidably removes the handle ( 17 ) in the direction indicated by arrow ( 3   b ). 
   Thus there has been described a novel compact powered caulking gun that will hopefully improve the dispensing of caulk, adhesive or other viscous materials.